Toll-like receptors

ABSTRACT

The present invention relates to toll-like receptors, to cells comprising such toll-like receptors, to methods for the detection of immunostimulatory oligodeoxynucleotides wherein such methods use such toll-like receptors, to immunostimulatory oligodeoxynucleotides detected by use of this method, to the use of such immunostimulatory oligodeoxynucleotides in medicine and to vaccines comprising such immunostimulatory oligodeoxynucleotides.

The present invention relates to hybrid toll-like receptors, to cells comprising such toll-like receptors, to methods for the detection of immunostimulatory oligodeoxynucleotides wherein such methods use such toll-like receptors, to immunostimulatory oligodeoxynucleotides detected by use of this method, to the use of such immunostimulatory oligodeoxynucleotides in medicine and to vaccines comprising such immunostimulatory oligodeoxynucleotides.

During the past two decades, it has emerged in immunological science that the vertebrate immune system possesses mechanisms to detect microbial infection and to trigger rapid immune activation via the receptor-mediated recognition of unique and conserved characteristics of pathogens, the so-called pathogen-associated molecular patterns (PAMPs) interacting with cognate host pathogen recognition receptors (PRRs) (Iwasaki A, Medzhitov R. 2001 and Medzhitov R., 2009).

It is now clear that certain forms of pathogen deoxyribonucleic acid (DNA) are amongst these PAMPs. In 1995 it was reported that non-methylated CpG motifs in bacterial DNA trigger murine B-cell activation (Krieg et al. 1995). This study generated for the first time a link between the specific recognition of bacterial immunostimulatory non-methylated CpG-containing DNA and the previously recognized CpG suppression as well as the widespread CpG methylation in mammalian DNA. The most effective B cell stimulatory non-methylated CpG oligodeoxynucleotide (CpG ODN) was shown to possess the sequence element GACGTT.

The next landmark paper in the field was published by Shizuo Akira's laboratory in Osaka/Japan (Hemmi et al. 2000). By a gene cloning and a targeted gene knockout approach in mice it could be unequivocally shown, that the cellular response in mice to CpG-ODNs is mediated by the toll-like receptor 9 (TLR9). Subsequently it was shown that the CpG-ODNs are agonists for TLR9 signaling predominantly via the NF kappa-B pathway (Medzhitov 2001). In the following decade, quite a number of studies have been published on basic research topics and on general potential immunotherapeutic applications (e. g. reviewed in Krieg 2002, 2003, 2006; Klinman 2004, Vollmer 2005, Wilson et al. 2006, Kindrachuk et al. 2008, Dorn and Kippenberger 2008, Vollmer and Krieg 2009, Wilson et al. 2009). A number of review articles focus on anti-infective applications of CpG-ODNs (Krieg 2007), the use of TLR9 agonists in the treatment of cancer (Krieg 2007, Weiner 2009), TLR9 activation for asthma and allergy treatment (Kline 2007, Kline and Krieg 2008, Fonseca and Kline 2009) and as vaccine adjuvants (Klinman et al. 2004, Klinman 2006, Daubenberger 2007, Wagner 2009, Mutwiri et al. 2009, Klinman et al. 2009).

CpG ODNs have also been described and discussed as immunostimulatory agents and vaccine adjuvants in veterinary applications, particularly in bovines, pigs, sheep, dogs, chicken and fish (Babiuk et al. 2003, Carrington and Secombes 2006, Griebel et al. 2005, Mutwiri et al. 2003, Singh and O'Hagan 2003, Werling and Jungi 2003).

The design of specific CpG ODN's as immune modulators for both human and non-human species has so far been quite random. The reason for this is multi-factorial; first of all there is no knowledge about correlation between immune modulatory CpG motifs for human TLR's and for TLR's in non-human mammalian species. Secondly, there are no in vitro cell-systems comprising a mammalian TLR available, that have a sufficiently low signal to noise level to allow for selective testing of the effects of very low concentrations of CpG ODN's. Moreover, there are no high-throughput screening methods available and even if there were, there is no clear correlation between in vivo versus in vitro efficacy of CpG ODN's as immuno-modulators.

In the PCT Patent Application with Application number PCT/EP2011/074211, unpublished at the filing date of the present invention, the inventors have described an in vitro cell-system that is suitable for reproducible in vitro testing and selection of CpG ODN's as immune modulators for use in poultry. This system is based upon the cloning and heterologous expression of TLR21, the functional homologue of TLR9 in chickens.

In order to develop a comparable system for testing CpG ODN's as immune modulators for mammals, both for human species and for non-human species such as canine, bovine and porcine species, it was decided to use a comparable approach, however now based upon the cloning and expression of i.a. canine, bovine and porcine toll-like receptor TLR9.

To this end, a clonal line of HEK293 cells was used that contains in its genome an integrated version of pNifTy2-SEAP (Invivogen), that provides an NF-κB activation reporter gene assay based on the measurement of secreted alkaline phosphatase (SEAP) production (See Examples section). Such cell lines were shown by the inventors to have broad utility in experiments aiming at stable functional expression of TLR1/2, TLR2/6, TLR3, TLR4, TLR5, TLR7 and TLR8 isolated from various vertebrate (bovine, canine, porcine, chicken) species.

Against this background it was to be expected that expression of bovine, canine and porcine TLR9 should be straightforward, an expectation boosted further by the exceptionally well-functioning HEK293-pNifTy2-SEAP-based functional expression of the chicken TLR9 functional homologue, TLR21.

However, repeated transfection experiments with bovine, canine and porcine TLR9 failed to yield cell lines that could be stimulated with known standard TLR9 agonists, such as 2006-PTO (TCGTCGTTTTGTCGTTTTGTCGTT) or 2007-PTO (TCGTCGTTGTCGTTTTGTCGTT), despite the fact that the selection for plasmid introduction (G418 or hygromycin) worked out successfully. Only in a few experiments, weak signals were initially seen in polyclonal transfectant pools. These signals disappeared upon further cell line cultivation and could not be rescued by single cell cloning. Similar experiments were performed with another NF-κB activation reporter gene containing cell type, the bovine macrophage cell line BOMAC-pNifTy2-SEAP. The outcome was essentially the same as seen previously in HEK293-pNifTy2-SEAP.

The reasons for the unexpected failure of functional expression (as shown by SEAP signal) remained unknown. An attempt to overcome the problem by using 293XL/null cells (InvivoGen), expressing the human anti-apoptotic Bcl-XL gene did also not result in sufficiently high SEAP expression levels.

Thus, there still is a need for selective and sensitive systems for the selection of CpG ODN's having a high immuno-modulatory effect and therefore being effective in low doses in mammals.

It is one of the objectives of the present invention to provide such selective and sensitive CpG ODN selection systems.

It was surprisingly found now that a hybrid toll-like receptor, comprising a Toll-interleukin I receptor-resistance (TIR) domain of poultry TLR21 and a extracellular ligand-binding domain of mammalian TLR9 is capable of overcoming the problem of low functional expression or non-expression as identified above.

TLRs are well-conserved type I transmembrane TM proteins composed of an N-terminal signal peptide, an extracellular ligand-binding domain containing leucine rich repeats, a single TM domain, and a cytoplasmic region largely comprised of the Toll-interleukin I receptor-resistance (TIR) domain.

Merely as an example: the extracellular domain of mouseTLR9 spans the region from a.a. 1 to 820, the transmembrane domain spans the region from a.a. 820-838 and the cytoplasmic domain spans the region from a.a. 838 to 1032. The TIR domain spans the region from a.a. 872-1032. (Kajita et al, BBRC 343: 578-584 (2006)).

The compartmentalization of TLR9 and of the poultry homologue TLR21 differs to a certain extent from that of TLR1, 2, 4, 5 and 6 in the sense that the part of TLR9 and 21 referred to as the “extracellular domain” is located in the endolysosome. As a consequence the TM region of TLR9/21 spans the endolysosomal membrane, not the cell's plasma membrane. This aspect and the cell biology of TLR's in general is reviewed by Barton G. M. and Kagan, J. C. in Nature Reviews 9; 535-542 (2009).

Merely as examples of mammalian TLR's, the sequences of bovine, porcine and canine TLR9 are given in SEQ ID NO's 1, 3 and 5 (nucleic acid sequence) and SEQ ID NO's 2, 4 and 6 (amino acid sequence) respectively.

It turns out that hybrid TLR's according to the invention, combining the CpG ODN specificity of the extracellular ligand-binding domain of mammalian TLR9 and the signaling properties of Toll-interleukin I receptor-resistance (TIR) domain of poultry TLR21 are accepted by the transfected cell without unacceptable adverse effects and at the same time they are very well suitable for the specific detection of CpG ODN's that are specifically immune stimulatory to mammalian species.

Transfection of e.g. HEK293 cells or MDCK cells with plasmids comprising DNA encoding such hybrid TLR's resulted in stable expression of hybrid TLR's which in turn led to marked NF-κB activation upon stimulation with exogenous CpG ODN's known to be active in mammals, such as 2006-ODN and 2007-ODN.

Thus, a first embodiment of the present invention relates to a hybrid toll-like receptor, characterised in that said hybrid toll-like receptor comprises a Toll-interleukin I receptor-resistance (TIR) domain of poultry TLR21 and a extracellular ligand-binding domain of mammalian TLR9.

The origin of the transmembrane region (TM region) and the non-TIR related part of the cytoplasmic domain is not critical, in the sense that these may independently originate from TLR 9 or TLR21.

In a preferred form of this embodiment, the extracellular ligand-binding domain of mammalian TLR9 is of human, bovine, porcine or canine origin.

Examples of hybrid TLR's according to the invention where the extracellular ligand-binding domain of mammalian TLR9 is of bovine, porcine or canine origin, are given in SEQ ID NO's 8, 10 and 12 (nucleic acid sequence) and SEQ ID NO's 9, 11 and 13 (amino acid sequence) respectively.

An “immunostimulatory non-methylated oligodeoxynucleotide” refers to an oligodeoxynucleotide, which contains a non-methylated cytidine-phosphate-guanosine di-nucleotide sequence that stimulates the initiation of signaling cascades leading to activation of transcription factors such as NF-κB or Interferon Regulatory Factor 3 (IRF3). It is this activation that in turn results in the expression of inflammatory cytokines and other cellular activation events. NF-κB binding sites and gene expression influenced by NF-κB are i.a. described by Schindler and Baichwal (1994).

The term oligodeoxynucleotide means a short nucleic acid polymer of deoxynucleotides; i.e. a molecule comprising a multitude of deoxyriboses, linked to a phosphate group and to an exchangeable organic base. Such an organic base is a substituted pyrimidine or a substituted purine. Examples are cytosine and thymine respectively adenine and guanine.

The oligonucleotides according to the invention may comprise modifications. Examples of such modifications are e.g. modifications in the phosphodiester internucleoside bridge located at the 3′ and/or 5′ end of a nucleoside. Such modifications relate i.a. to the replacement of a phosphodiester by e.g. a phosphorothioate or a phosphorodithioate.

Basically, depending upon the way of synthesis, usual common types of bonds between two nucleotides are: phosphodiester (PDE) bonds and phosphorothioate (PTO) bonds. In order to improve the stability and the immunostimulatory effect of CpG ODN's, the building blocks of synthetic oligodeoxynucleotides may be provided with phosphorothioates, so that they form PTO bonds.

Other modifications are e.g. replacements of a phosphodiester bridge by a dephospho bridge. Examples of dephospho bridges are methylhydroxylamine, formacetal and dimethylenesulfone groups.

Still other modifications are modifications that concern the replacement of a natural nucleoside base by a non-natural nucleoside base such as 5-fluorocytosine, 7-deaza-7-substituted guanine, 7-deaza-8-substituted guanine, 2-thiouracil, dihydrouracil, 5-bromo-cytosine, 6-substituted cytosines or N4-substituted cytosines.

Again other modifications are modifications concerning the replacement of a sugar unit; a β-ribose sugar or a β-D-2′-ribose sugar unit by a modified sugar unit such as e.g. an L-2′-deoxyribose or 2′-L-arabinose.

A text book giving further insight in oligonucleotides is e.g. “PCR Primer: A Laboratory Manual”, Second Edition, 2003, Edited By Carl W. Dieffenbach, National Institute of Allergy and Infectious Diseases; Gabriela S. Dreksler, Uniformed Services University of the Health Sciences, Cold Spring Harbor Laboratory Press ISBN 978-087969654-2.

For the detection of new CpG ODN's, a system is required that comprises cells that comprise a hybrid TLR according to the invention

Thus, a second embodiment of the present invention relates to cells that comprise a hybrid TLR according to the invention.

As mentioned (vide supra), CpG ODN agonists for TLR9 signal predominantly via the NF kappa-B (NF-κB) pathway (Medzhitov 2001).

The detection of the effect of a CpG ODN on the occurrence and the amount of a compound of the (NF-κB) pathway in a cell is therefore indicative for its activity as a PAMP.

Brownlie at al. (2009) describe an NF-κB luciferase based reporter system. Other reporter systems are e.g. based upon IL-8 transcript measurement or cytokine secretion or the detection of NO secretion.

Thus, a preferred form of this embodiment relates to a cell according to the invention, characterised in that said cell comprises a plasmid comprising an NF-κB reporter gene.

Such reporter systems as mentioned above, although useful, have the disadvantage that they are not very sensitive. For a precise determination of the activity of existing and newly developed CpG ODN's, a sensitive detection system is a prerequisite.

The inventors now used a detection system in the present invention, that turned out to be surprisingly sensitive. This system is based upon the use of an enzyme called secreted alkaline phosphatase (SEAP) as a reporter enzyme encoded by the reporter gene. SEAP is a reporter enzyme in mammalian systems (Yang et al., 1997). In this system, SEAP expression is controlled by 5 NF-κB transcription factor binding sites combined with the ELAM promoter (J. Biol. Chem. 1991, Feb. 5; 266(4): 2466-73).

Therefore, a more preferred form of this second embodiment relates to cells according to the invention wherein the reporter gene encodes a secreted alkaline phosphatase (SEAP). The SEAP system is used with para-nitrophenylphosphate (pNPP) as a substrate.

Another important improvement over existing systems is the introduction and stable maintenance in cells of the plasmid carrying the reporter gene.

Up till now, all detection systems used transient transfection of cells with the reporter gene. Such transient systems do not allow for a reliable side-by-side comparison of the efficacy of CpG ODN's.

Usually, stable maintenance of a plasmid is obtained by growing the cells under the pressure of one or more selective agents, such as antibiotics for which a resistance gene is present on the plasmid. Loss of the plasmid would then cause the cell that lost the plasmid to die. Remaining viable cells would still harbour the plasmid. Stable means that the plasmid remains present in the cell after several cell division cycles, preferably integrated in the cell genome.

It is due to the introduction and stable maintenance in cells of the reporter gene that now for the first time a reproducible dose/response curve for CpG ODN's can be made. Such curves are essential if a reliable comparison between various CpG ODN's activity is to be made.

Thus, another preferred form of this second embodiment relates to a cell according to the invention that comprises a plasmid encoding an NF-κB reporter gene, which plasmid is stably maintained in the cell. Such cells are very suitable for use in the screening of CpG molecules, more specifically the screening of CpG molecules according to the invention.

The Examples give ample guidance about how to obtain such a cell comprising a plasmid encoding a reporter gene that can be stably maintained in the cell.

Basically, any cell or cell line carrying a hybrid TLR according to the invention that allows introduction and preferably the stable maintenance of a plasmid carrying a NF-κB reporter gene, preferably the SEAP gene as described above is suitable for testing TLR9-specific CpG ODN's. An example of such a suitable cell line for testing TLR9-specific CpG ODN's is the cell line HEK293 ((ATCC number CRL-1573).

A preferred cell line for testing TLR9-specific CpG ODN's is the cell line Madin Darby canine kidney (ATCC number CCL-34) (MDCK).

Therefore, another preferred form of this second embodiment relates to a cell according to the invention wherein the cell is a HEK293 cell, preferably an MDCK cell.

The methods and cell lines described in detail in the Examples section of the present invention allow for the first time to make a reliable side-by-side comparison between various CpG ODN's for use in mammalian species.

Thus, still another embodiment of the present invention relates to a method for the detection of immunostimulatory oligodeoxynucleotides according to the invention wherein that method comprises the steps of a) contacting an oligodeoxynucleotide with a cell according to the invention, b) detecting the level of product of the reporter gene.

In a preferred form of this method, the product of the reporter gene is SEAP

As shown in the Examples below, the hybrid toll-like receptors according to the invention have been used extensively for the identification of new CpG ODN's.

The CpG oligodeoxynucleotides according to the invention are in most cases active in double digit or even sometimes in single digit nanomolar concentrations, both in the in vitro test system and in vivo.

The half-maximal effective concentration (EC50) of an oligodeoxynucleotide is the amount of oligodeoxynucleotide that is necessary to induce an amount of the reporter enzyme SEAP (that produces the colored product absorbing at 405 nm) in the reporter cells that gives a half-maximal absorption change over time.

The Vmax indication given is an indication of the speed with which the chromogenic substrate of SEAP is turned into a colored component with an absorption of 405 nm. A high Vmax indicates that the CpG ODN is capable of rapidly inducing a TLR-reaction.

The following new immunostimulatory non-methylated oligodeoxynucleotides were found to have a low EC50 (double or even single digit nM concentrations) and thus to be very effective already in very low concentrations:

[gacgtt]_(n) wherein n ≧ 4 [gacgatcgtc]_(n) wherein n ≧ 3 [tcgtcgttttcg]_(n) wherein n ≧ 3 [tcgtcgttgtcgttttgtcgtt]_(n) wherein n ≧ 2 (t_(x)[ttcgtt]t_(y))_(n) wherein n ≧ 5,    x = 0-5 and y = 0-5 [ttcgtN₁]_(n) wherein N₁ = t or c   and wherein n ≧ 5 [N₁tcgtc]_(n) wherein N₁ = t or c   and wherein n ≧ 5 [gN₁cgtt]_(n) werein n ≧ 4 and N₁ = a or t [tcg]_(x) wherein n ≧ 6 [tcgN1]_(n) wherein N1 = c or g and n ≧ 6 [N1cgt]_(n) wherein N1 = g or c or a or t  and n ≧ 6 [acga]_(n) wherein n ≧ 6

It should be kept in mind that all of these new immunostimulatory non-methylated oligodeoxynucleotides are of the phosphorothioate (PTO) type.

Therefore, again another embodiment of the present invention relates to immunostimulatory non-methylated PTO oligodeoxynucleotides having any of the 12 general formulae given above.

It was generally found that the activity of the oligodeoxynucleotides increases when n increases. This effect is leveling when n increases. Basically, the number n of the backbone structure should therefore be at least the number of n as indicated. Preferably, the upper range of n is n≦100, merely because of the fact that the longer the synthetic sequence the more difficult it is to make. In practice therefore a more preferable upper range of n is n≦40, even more preferable n≦20.

It is very well possible to link an oligodeoxynucleotide according to the invention to a carrier or hapten, via a reactive chemical group. Such linkage enhances the immunostimulatory effect of the combined molecules.

Mere examples of such components are e.g. digoxigenin, aminohexyl-, Texas red and biotin. Preferred carriers or haptens are 3′- and 5′-labeled Texas red and 5′-labeled digoxigenin. The linkage of oligodeoxynucleotides to haptens/carriers is well-known in the art.

Thus, a preferred form of this embodiment relates to an immunostimulatory non-methylated PTO oligodeoxynucleotide having one of the 12 general formulae given above wherein said oligodeoxynucleotide is coupled to a carrier or hapten.

Another embodiment of the invention relates to a vector comprising an immunostimulatory non-methylated oligodeoxynucleotide according to the invention. Such a vector can be a nucleic acid molecule such as a plasmid, a virus, a bacteriophage or any other vector used in molecular biology. Merely as an example: a vector comprising an immunostimulatory non-methylated oligodeoxynucleotide can e.g. be a DNA molecule such as a plasmid that can be multiplied in bacteria, into which an immunostimulatory non-methylated oligodeoxynucleotide according to the invention has been cloned. Such a plasmid preferably has an active origin of replication, causing high numbers of the plasmid to be present in the host. Growing such bacteria on a large scale followed by isolation of the plasmids provides an alternative for the synthetic production of the immunostimulatory non-methylated oligodeoxynucleotide according to the invention. It should be kept in mind that this embodiment only applies to immunostimulatory non-methylated oligodeoxynucleotides of the PDE type.

One of the aims of the present invention is to provide new CpG ODN's that can be used as successful immunostimulating components in vaccines that prevent or combat infectious disease together with an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier.

In general, the term antigen component refers to a composition of matter that comprises at least one epitope that can induce, stimulate or enhance an immune response when administered to a human or an animal.

The antigen component may be any kind of antigen component but preferably is derived from a micro-organism or virus that in its wild-type form is pathogenic to humans or animals.

The antigen component can be the whole pathogen, preferably in an inactivated or attenuated form, an extract of the pathogen or (an immunogenic part of) an immunogenic protein of the pathogen.

If the antigen component is (an immunogenic part of) an immunogenic protein of the pathogen, that immunogenic protein is preferably expressed in and recovered from in vitro cultured cells.

Therefore, another embodiment relates to a vaccine for preventing or combating infectious disease characterised in that said vaccine comprises an immunostimulating amount of an oligodeoxynucleotide according to the invention and/or a vector according to the invention, an immunogenic amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier.

The skilled person will understand that the immunostimulating amount of the oligodeoxynucleotide and the immunogenic amount of the antigen component are strongly interrelated. It is one of the merits of the present invention that new oligodeoxynucleotide are provided that can lower the amount of antigen component that is necessary to prevent or combat infectious disease.

The amount of antigen component that is necessary to prevent or combat infectious disease is referred to as the immunogenic amount of the antigen component.

An immunostimulating amount of the oligodeoxynucleotide is the amount that is capable of decreasing the immunogenic amount of the antigen component, i.e. the amount of the antigen component that is necessary to prevent or combat an infectious disease.

So basically, the wording “immunostimulating amount of the oligodeoxynucleotide” and “immunogenic amount” must be seen in relation to each other.

It goes without saying that, if the vaccine comprises genetic information encoding an antigen component, the amount of antigen component expressed by this genetic information should be enough to prevent or combat infectious disease, i.e.; it must be an immunogenic amount.

The fact that the non-methylated oligodeoxynucleotides according to the invention are immunostimulatory, means that they enhance the immunological efficacy of antigen components in vaccines. For that reason, vaccines according to the invention will in many cases comprise less of the antigen component or the genetic information encoding the antigen component than would be the case if no oligodeoxynucleotides according to the invention would be present.

In some cases an antigen component as such, without the addition of immunostimulatory oligonucleotides, may have such low immunogenic properties that high amounts must be given anyway, albeit without reaching the desired immunogenic level. In such cases, the antigen component can be given in the usual high concentration, however now together with an oligodeoxynucleotide according to the invention in order to so obtain the desired level of immunogenicity.

Thus, the amount of the antigen component or the genetic information encoding the antigen component to be administered with an oligonucleotide according to the invention would as a rule of thumb be equal or below the amount given in the absence of the oligonucleotide. The skilled person involved in the manufacturing of a specific vaccine, would know that amount for that specific vaccine. Also, the Examples give e.g. guidance for the amount of antigen components to be used, e.g. for a rabies vaccine for canine species.

The amount of the oligodeoxynucleotide according to the invention that needs to be administered together with the antigen component or the genetic information encoding the antigen component depends both on the selected oligodeoxynucleotide and the antigen component.

A very suitable amount of oligodeoxynucleotide according to the invention would usually vary between 1 and 100 nanomol. Very good in vivo results have e.g. been obtained with 5-50 mg of oligodeoxynucleotides according to the invention with an average length of 30 deoxynucleotides that were shown to be active in in vitro tests in the nanomolar range.

If an oligodeoxynucleotide is chosen from the group of oligodeoxynucleotides that are active in the picomolar range, the skilled person would realise that amounts below, possibly far below, 1 nanomol, i.e. picomol amounts (e.g. 100-1000 ng), would be worth testing before testing nanomolar amounts. The skilled person should be aware of the fact that there may be an optimal amount for each of the oligodeoxynucleotides according to the invention.

Vaccines according to the invention comprise a pharmaceutically acceptable carrier. The nature of this carrier depends i.a. upon the route of administration. If the administration route is through the oral or intranasal route, the carrier could be as simple as sterile water, a physiological salt solution or a buffer. If injection is the preferred route, the carrier should preferably be isotonic and have pH restrictions that make it suitable for injection. Such carriers however are extensively known in the art.

Vaccines according to the invention may, in addition to the antigen component or the genetic information encoding the antigen component, and an oligodeoxynucleotide according to the invention, comprise an adjuvant. Adjuvants in general are substances that boost the immune response of the host in a non-specific manner.

Many adjuvants are known in the art to be suitable, such as Freund's Complete and Incomplete adjuvant, vitamin E, non-ionic block polymers and polyamines such as dextran sulphate, carbopol and pyran, alum hydroxide. Also frequently used are alumin phosphate, saponins, vegetable oils such as tocopherol and mineral oils. Very efficient adjuvants are oil-in-water emulsions and especially water-in-oil emulsions, further also referred to as oil-in-water adjuvants and water-in-oil adjuvants. Such emulsions are well-known in the art. Thus, preferably, the vaccine comprises a water-in-oil adjuvant.

Preferably the antigen component is, or is derived from a virus or micro-organism that in its wild-type form is pathogenic to humans, porcine, canine or bovine species.

For a large number of pathogens, vaccines are commercially available. These pathogens are listed below.

Thus, more preferably said virus or micro-organism is selected from the group consisting of human papillomavirus, a bacterium causing tuberculosis, diphtheria, pertussis, tetanus, pneumonia or meningitis, measles virus, poliomyelitis virus, hepatitis B virus, Leptospira, Mycobacterium hyopneumomiae, Bovine respiratory syncytium virus, Foot-and-mouth disease virus, Bovine Viral Diarrhoea virus, Porcine Respiratory and Reproductive Syndrome virus, canine parvovirus, canine parainfluenza virus, canine coronavirus, canine distemper virus, canine adenovirus, porcine Circovirus 2, Bovine Herpesvirus, rabies virus, classical swine fever virus, equine Herpesvirus, porcine parvovirus, Escherichia coli, Pasteurella (i.a. P. multocida), Bordetella (i.a. B. bronchiseptica), Pseudorabies virus, Erysipelothrix, Haemophilus parasuis, Bovine parainfluenza virus, Mannheimia (i.a. M. haemolytica), Fusobacterium, Lawsonia intracellularis, Streptococcus equi, Chlamidophila, Actinobacillus pleuropneumoniae, Brucella abortus, Dictyocaulis, Toxoplasma gondii, Babesia (i.a. B. canis), Neospora, Giardia, Sarcocystis and Leishmania.

Again another embodiment of the present invention relates to an immunostimulatory non-methylated oligodeoxynucleotide according to the invention in combination with an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier for use as a medicament.

Still another embodiment of the present invention relates to an immunostimulatory non-methylated oligodeoxynucleotide according to the invention in combination with an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier for use in preventing or combating infectious disease in mammalian species, preferably human, porcine, bovine and canine species.

LEGEND TO THE FIGURES

FIG. 1: MDCK (canine)-pNifTyhyg: reactivity with different PAMPs. Vertical axis: mOD450 nm/min.

FIG. 2: MDCK (canine)-pNifTyhyg: reactivity with different PAMPs. Vertical axis: mOD450 nm/min.

FIG. 3: MDcanK-pNifTyhyg-single cell clones 1-46-huTNF-alpha stimulation. Horizontal axis: from left to right; clone 1 to clone 46, pool and control

FIG. 4: PCR “sewing” strategy.

FIG. 5: canTLR9-21MDCKpNifTyhyg-single cell clones 1-54-2006-PTO stimulation. Horizontal axis: from left to right; clone 1 to clone 54, followed by “canTLR9-TLR21-pool” (the polyclonal cell line before single cell cloning). The reactivity is given in pairs of bars: the left bar (gray) is the level of stimulation with 1 microM of 2006-PTO, the right bar (black is the control)

FIG. 6-18: MDCK-pNifTyhyg-pIRESpuro-canTLR9-21 fusion: stimulation with several PAMPs as indicated

FIG. 19: MDCK-pNifTyhyg-pigTLR9/TLR21-single cell clones 1-75 ODN-2006-PTO stimulation. Horizontal axis: from left to right; clone 1 to clone 75, pool, “canis-TLR9/21-clone17” (dog TLR9-21 fusion clonal cell line (no 17) as a positive control) and “MDCK-pNifTyhyg” (the basal MDCK cell line used for the transfection experiment).

FIG. 20-31: MDCK-pNifTyhyg-pigTLR9/TLR21-fusion, tested with different PAMPs as indicated.

FIG. 32: Antibody titer of Nobivac rabies vaccine with and without hio-tcg-8-PTO as indicated.

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EXAMPLES Example 1 Gene Cloning of Bovine Toll-Like Receptor 9 (TLR-9)

Fresh bovine spleen was obtained from a local slaughterhouse as a source of bovine TLR9 messenger RNA (mRNA). Total RNA was prepared from bovine spleen tissue essentially as outlined by Chomczynski and Sacchi (1987) using a commercial kit and its instructions (TRIZOL®, GIBCOBRL). From the bovine spleen total RNA, first strand cDNA was synthesized, essentially as described by the supplier of the reverse transcriptase (-Expand Reverse Transcriptase, Roche). Primer were designed for the polymerase chain reaction (PCR) amplification of bovine TLR9 (Genbank AY859726) from the start codon region to a 3′UTR region downstream of the stop codon (Bov-TLR9-for and Bov-TLR9-rev, see below). However, initial PCR experiments (Expand High Fidelity PCR kit, Roche) using bovine spleen first strand cDNA aiming at the amplification of the full length product (expected: ˜3100 bp) proved to be repeatedly negative. Closer inspection of the bovine TLR9 gene indicated a high GC content (−64%). Therefore, it was decided to test a PCR system optimized for this particular problem (Advantage™ GC2, Clontech). The corresponding PCR reaction yielded a weak DNA fragment of the expected size (˜3100 bp).

Primer Sequences:

Bov-TLR9-for GGGTACCATGGGCCCCTACTGTGCCCCGCAC Bov-TLR9-rev GTCTAGAGTCTGTGCTATTCGGCTGTCGTGG

Cloning of the PCR fragment into pCR2.1-Topo (Invitrogen) was performed, and four clones were sequenced to identify a PCR error-free version (pCR2.1-Topo-bovineTLR9). By exploiting primer-introduced KpnI and XbaI restriction enzyme sites, the bovine TLR9 insert was excised, agarose gel-purified and subcloned into the KpnI/XbaI-cut mammalian expression vectors pcDNA3.1(neo) and pcDNA3.1(hyg) (both Invitrogen), yielding pcDNA3.1(neo)-bovineTLR9 and pcDNA3.1(hyg)-bovineTLR9, respectively. The corresponding inserts were resequenced (see below).

pcDNA3.1 insert sequence bovine TLR9 (primer sequences underlined, start/stop codons highlighted bold), 3090 bp.

GGTACC

GGCCCCTACTGTGCCCCGCAC CCCCTTTCTCTCCTGGTGC AGGCGGCGGCACTGGCAGCGGCCCTGGCCGAGGGCACCCTGCCTGCCTTC CTGCCCTGTGAGCTCCAGCCCCATGGTCAGGTGGACTGCAACTGGCTGTT CCTGAAGTCTGTGCCGCACTTTTCGGCTGGAGCCCCCCGGGCCAATGTCA CCAGCCTCTCCTTAATCTCCAACCGCATCCACCACTTGCATGACTCTGAC TTCGTCCACCTGTCCAACCTGCGGGTCCTCAACCTCAAGTGGAACTGCCC GCCGGCCGGCCTCAGCCCCATGCACTTCCCCTGCCGTATGACCATCGAGC CCAACACCTTCCTGGCTGTGCCCACCCTGGAGGAGCTGAACCTGAGCTAC AACGGCATCACGACCGTGCCTGCCCTGCCCAGTTCCCTCGTGTCCCTGTC GCTGAGCCACACCAGCATCCTGGTGCTAGGCCCCACCCACTTCACCGGCC TGCACGCCCTGCGCTTTCTGTACATGGACGGCAACTGCTACTACATGAAC CCCTGCCCGCGGGCCCTGGAGGTGGCCCCAGGCGCCCTCCTCGGCCTGGG CAACCTCACGCACCTGTCGCTCAAGTACAACAACCTCACGGAGGTGCCCC GCCGCCTGCCCCCCAGCCTGGACACCCTGCTGCTGTCCTACAACCACATT GTCACCCTGGCACCCGAGGACCTGGCCAACCTGACTGCCCTGCGCGTGCT TGACGTGGGTGGGAACTGCCGCCGCTGCGACCACGCCCGCAACCCCTGCA GGGAGTGCCCAAAGAACTTCCCCAAGCTGCACCCTGACACCTTCAGTCAC CTGAGCCGCCTCGAAGGCCTGGTGTTGAAGGACAGTTCTCTCTACAAACT AGAGAAAGATTGGTTCCGCGGCCTGGGCAGGCTCCAAGTGCTCGACCTGA GTGAGAACTTCCTCTATGACTACATCACCAAGACCACCATCTTCAACGAC CTGACCCAGCTGCGCAGACTCAACCTGTCCTTCAATTACCACAAGAAGGT GTCCTTCGCCCACCTGCACCTAGCGTCCTCCTTTGGGAGTCTGGTGTCCC TGGAGAAGCTGGACATGCACGGCATCTTCTTCCGCTCCCTCACCAACATC ACGCTCCAGTCGCTGACCCGGCTGCCCAAGCTCCAGAGTCTGCATCTGCA GCTGAACTTCATCAACCAGGCCCAGCTCAGCATCTTTGGGGCCTTCCCGA GCCTGCTCTTCGTGGACCTGTCGGACAACCGCATCAGCGGAGCCGCGACG CCAGCGGCCGCCCTGGGGGAGGTGGACAGCAGGGTGGAAGTCTGGCGATT GCCCAGGGGCCTCGCTCCAGGCCCGCTGGACGCCGTCAGCTCAAAGGACT TCATGCCAAGCTGCAACCTCAACTTCACCTTGGACCTGTCACGGAACAAC CTGGTGACAATCCAGCAAGAGATGTTTACCCGCCTCTCCCGCCTCCAGTG CCTGCGCCTGAGCCACAACAGCATCTCGCAGGCGGTTAATGGCTCCCAGT TCGTGCCGCTGACCAGCCTGCGAGTGCTCGACCTGTCCCACAACAAGCTG GACCTGTACCATGGGCGCTCATTCACGGAGCTGCCGCAGCTGGAGGCACT GGACCTCAGCTACAACAGCCAGCCCTTCAGCATGCAGGGCGTGGGCCACA ACCTCAGCTTCGTGGCCCAGCTGCCCTCCCTGCGCTACCTCAGCCTTGCG CACAATGGCATCCACAGCCGCGTGTCACAGAAGCTCAGCAGCGCCTCGTT GCGCGCCCTGGACTTCAGCGGCAACTCCCTGAGCCAGATGTGGGCCGAGG GAGACCTCTATCTCTGCTTTTTCAAAGGCTTGAGGAACCTGGTCCAGCTG GACCTGTCCGAGAACCATCTGCACACCCTCCTGCCTCGTCACCTGGACAA CCTGCCCAAGAGCCTGCGGCAGCTGCGTCTCCGGGACAATAACCTGGCCT TCTTCAACTGGAGCAGCCTGACCGTCCTGCCCCGGCTGGAAGCCCTGGAT CTGGCAGGAAACCAGCTGAAGGCCCTGAGCAACGGCAGCCTGCCGCCTGG CATCCGGCTCCAGAAGCTGGACGTGAGCAGCAACAGCATCGGCTTCGTGA TCCCCGGCTTCTTCGTCCGCGCGACTCGGCTGATAGAGCTTAACCTCAGC GCCAATGCCCTGAAGACAGTGGATCCCTCCTGGTTCGGTTCCTTAGCAGG GACCCTGAAAATCCTAGACGTGAGCGCCAACCCGCTCCACTGCGCCTGCG GGGCGGCCTTTGTGGACTTCCTGCTGGAGAGACAGGAGGCCGTGCCCGGG CTGTCCAGGCGCGTCACATGTGGCAGTCCGGGCCAGCTCCAGGGCCGCAG CATCTTCACACAGGACCTGCGCCTCTGCCTGGATGAGACCCTCTCCTTGG ACTGCTTTGGCCTCTCACTGCTAATGGTGGCGCTGGGCCTGGCAGTGCCC ATGCTGCACCACCTCTGTGGCTGGGACCTCTGGTACTGCTTCCACCTGTG TCTGGCCCATTTGCCCCGACGGCGGCGGCAGCGGGGCGAGGACACCCTGC TCTATGATGCCTTCGTGGTCTTCGACAAGGTGCAGAGTGCAGTGGCTGAT TGGGTGTACAACGAGCTCCGCGTGCAGCTGGAGGAGCGCCGGGGGCGCCG GGCGCTCCGCCTCTGCCTGGAGGAGCGAGACTGGCTCCCTGGTAAGACGC TCTTCGAGAACCTGTGGGCCTCGGTCTACAGCAGCCGCAAGACCATGTTC GTGCTGGACCACACGGACCGGGTCAGCGGCCTCCTGCGCGCCAGCTTCCT GCTGGCCCAGCAGCGCCTGTTGGAGGACCGCAAGGACGTCGTAGTGCTGG TGATCCTGCGCCCCGCCGCCTATCGGTCCCGCTACGTGCGGCTGCGCCAG CGCCTCTGCCGCCAGAGCGTCCTCCTCTGGCCCCACCAGCCCAGTGGCCA GGGTAGTTTCTGGGCCAACCTGGGCATAGCCCTGACCAGGGACAACCGTC ACTTCTATAACCGGAACTTCTGCCGGGGCC CCACGACAGCCGAA

CACAGACTCTAGA MGPYCAPHPLSLLVQAAALAAALAEGTLPAFLPCELQPHGQVDCNWLFLK SVPHFSAGAPRANVTSLSLISNRIHHLHDSDFVHLSNLRVLNLKWNCPPA GLSPMHFPCRMTIEPNTFLAVPTLEELNLSYNGITTVPALPSSLVSLSLS HTSILVLGPTHFTGLHALRFLYMDGNCYYMNPCPRALEVAPGALLGLGNL THLSLKYNNLTEVPRRLPPSLDTLLLSYNHIVTLAPEDLANLTALRVLDV GGNCRRCDHARNPCRECPKNFPKLHPDTFSHLSRLEGLVLKDSSLYKLEK DWFRGLGRLQVLDLSENFLYDYITKTTIFNDLTQLRRLNLSFNYHKKVSF AHLHLASSFGSLVSLEKLDMHGIFFRSLTNITLQSLTRLPKLQSLHLQLN FINQAQLSIFGAFPSLLFVDLSDNRISGAATPAAALGEVDSRVEVWRLPR GLAPGPLDAVSSKDFMPSCNLNFTLDLSRNNLVTIQQEMFTRLSRLQCLR LSHNSISQAVNGSQFVPLTSLRVLDLSHNKLDLYHGRSFTELPQLEALDL SYNSQPFSMQGVGHNLSFVAQLPSLRYLSLAHNGIHSRVSQKLSSASLRA LDFSGNSLSQMWAEGDLYLCFFKGLRNLVQLDLSENHLHTLLPRHLDNLP KSLRQLRLRDNNLAFFNWSSLTVLPRLEALDLAGNQLKALSNGSLPPGIR LQKLDVSSNSIGFVIPGFFVRATRLIELNLSANALKTVDPSWFGSLAGTL KILDVSANPLHCACGAAFVDFLLERQEAVPGLSRRVTCGSPGQLQGRSIF TQDLRLCLDETLSLDCFGLSLLMVALGLAVPMLHHLCGWDLWYCFHLCLA HLPRRRRQRGEDTLLYDAFVVFDKVQSAVADWVYNELRVQLEERRGRRAL RLCLEERDWLPGKTLFENLWASVYSSRKTMFVLDHTDRVSGLLRASFLLA QQRLLEDRKDVVVLVILRPAAYRSRYVRLRQRLCRQSVLLWPHQPSGQGS FWANLGIALTRDNRHFYNRNFCRGPTTAE.

The translated sequence was aligned with 10 bovine TLR9 full length cDNA sequences deposited in Genbank (September 2011, P8-141108-prot-280109.pro Bov-TLR9-NM_(—)183081.pro Bov-rom-TLR9-EF076723.pro Bov-ang-TLR9-EF076724.pro Bov-braf-TLR9-EF076725.pro Bov-brah-TLR9-EF076726.pro Bov-char-TLR9-EF076727.pro Bov-hol-TLR9-EF076728.pro Bov-lim-TLR9-EF076729.pro Bov-pied-TLR9-EF076731.pro Bov-TLR9-AY859726.pro). Alignment (ClustalW; DNAStar) of the 11 bovine TLR9 polypeptide sequences showed polymorphisms at 7 positions. In 5 cases the translated sequence of our TLR9 clone (P8-141108-prot-280109) conformed to the majority polypeptide sequence. In the two other positions, identical residues were found as in the Genbank sequence AY859726.

Therefore, it is concluded that a correct version of bovine TLR9 has been cloned.

Example 2 Gene Cloning of Porcine Toll-Like Receptor 9 (TLR-9)

Fresh porcine spleen was obtained from a local slaughterhouse as a source of porcine TLR9 messenger RNA (mRNA). Total RNA was prepared from porcine spleen tissue essentially as outlined by Chomczynski and Sacchi (1987) using a commercial kit and its instructions (TRIZOL®, GIBCOBRL). From the porcine spleen total RNA, first strand cDNA was synthesized, essentially as described by the supplier of the reverse transcriptase (Expand Reverse Transciptase, Roche).

Primer were designed for the polymerase chain reaction (PCR) amplification of porcine TLR9 (Genbank NM_(—)213958) from the start codon region to a 3′UTR region downstream of the stop codon (PigTLR9for1 and PigTLR9rev1, see below). However, initial PCR experiments using porcine spleen first strand cDNA aiming at the amplification of the full length product (expected: 3246 bp) proved to be repeatedly negative. Therefore, it was decided to take advantage of a unique Xho I site bisecting the porcine TLR9 gene into two approximately equally sized fragments (1501 bp and 1745 bp, respectively), that were more amenable for a PCR approach. To this end primer were designed upstream of the Xho I site in a forward direction and downstream of the Xho I site in a reverse direction (PigTLR9XhoI-for and PigTLR9XhoI-rev, see below), to give rise to PCR fragments overlapping near the unique XhoI site.

Primer Sequences:

PigTLR9for1 G AAGCTT ACCATGGGCCCCCGCTGCACCCTGCACCCC PigTLR9rev1 G GCGGCCGC TTACATGCCAGGCTGGGGGGTGGGGTG PigTLR9Xhol-for GGTGACAATCCAGTCGGAGATGTTTGCTCG PigTLR9Xhol-rev GGTCCAGCTTGTTGTGGGACAGGTCCAGC

PCR reactions (Expand High Fidelity PCR kit, Roche) were performed with the primer pairs PigTLR9for 1/PigTLR9XhoI-rev (for amplification of the 5′ gene fragment) and PigTLR9XhoI-for/PigTLR9rev1 (for amplification of the 3′ gene fragment). The corresponding PCR products were agarose gel-purified, cloned into pCR2.1-topo (Invitrogen), and three clones each were sequenced to identify PCR error-free versions. By exploiting vector-based and PCR fragment-based XhoI sites, the corresponding 5′- and 3′-PCR fragments were joined to the full length porcine TLR9 gene. From the corresponding construct (pCR2.1-Topo-porcineTLR9) the insert was excised by HindIII/NotI digestion, agarose gel-purified and subcloned into the HindIII/NotI-cut mammalian expression vectors pcDNA3.1(neo) and pcDNA3.1(hyg) (both Invitrogen), yielding pcDNA3.1(neo)-porcineTLR9 and pcDNA3.1(hyg)-porcineTLR9, respectively. The corresponding inserts were resequenced (see below).

pcDNA3.1 insert sequence porcine TLR9 (primer sequences underlined, start/stop codons highlighted bold, unique XhoI site highlighted)

GAAGCTTACC

GGCCCCCGCTGCACCCTGCACCC CCTTTCTCTCCTG GTGCAGGTGACAGCGCTGGCTGCGGCTCTGGCCCAGGGCAGGCTGCCTGC CTTCCTGCCCTGTGAGCTCCAGCCCCACGGCCTGGTGAACTGCAACTGGC TCTTCCTGAAGTCCGTGCCCCACTTCTCGGCGGCAGCGCCCCGGGCCAAC GTCACCAGCCTCTCCTTACTCTCCAACCGCATCCACCACCTGCACGACTC TGACTTCGTCCACCTGTCCAGCCTACGAACTCTCAACCTCAAGTGGAACT GCCCGCCGGCTGGCCTCAGCCCCATGCACTTCCCCTGCCACATGACCATC GAGCCCAACACCTTCCTGGCCGTGCCCACCCTGGAGGAGCTGAACCTGAG CTACAACAGCATCACGACCGTGCCTGCCCTGCCCGACTCCCTCGTGTCCC TGTCGCTGAGCCGCACCAACATCCTGGTGCTAGACCCCACCCACCTCACT GGCCTACATGCCCTGCGCTACCTGTACATGGATGGCAACTGCTACTACAA GAACCCCTGCCAGGGGGCGCTGGAGGTGGTGCCGGGTGCCCTCCTCGGCC TGGGCAACCTCACACATCTCTCACTCAAGTACAACAATCTCACGGAGGTG CCCCGCAGCCTGCCCCCCAGCCTGGAGACCCTGCTGTTGTCCTACAACCA CATTGTCACCCTGACGCCTGAGGACCTGGCCAATCTGACTGCCCTGCGCG TGCTTGATGTGGGGGGGAACTGCCGCCGCTGTGACCATGCCCGCAACCCC TGCAGGGAGTGCCCAAAGGACCACCCCAAGCTGCACTCTGACACCTTCAG CCACCTGAGCCGCCTCGAAGGCCTGGTGTTGAAAGACAGTTCTCTCTACA ACCTGGACACCAGGTGGTTCCGAGGCCTGGACAGGCTCCAAGTGCTGGAC CTGAGTGAGAACTTCCTCTACGACTGCATCACCAAGACCACGGCCTTCCA GGGCCTGGCCCGACTGCGCAGCCTCAACCTGTCCTTCAATTACCACAAGA AGGTGTCCTTTGCCCACCTGCACCTGGCACCCTCCTTTGGGCACCTCCGG TCCCTGAAGGAGCTGGACATGCATGGCATCTTCTTCCGCTCGCTCAGTGA GACCACGCTCCAACCTCTGGTCCAACTGCCTATGCTCCAGACCCTGCGCC TGCAGATGAACTTCATTAACCAGGCCCAGCTCAGCATCTTTGGGGCCTTC CCTGGCCTGCTGTACGTGGACCTATCGGACAACCGCATCAGCGGAGCTGC AAGGCCAGTGGCCATTACTAGGGAGGTGGATGGTAGGGAGAGGGTCTGGC TGCCTTCCAGGAACCTCGCTCCACGTCCACTGGACACTCTCCGCTCAGAG GACTTCATGCCAAACTGCAAGGCCTTCAGCTTCACCTTGGACCTGTCTCG GAACAACCTGGTGACAATCCAGTCGGAGATGTTTGCTCGCCTCTCACGCC TCGAGTGCCTGCGCCTGAGCCACAACAGCATCTCCCAGGCGGTCAATGGC TCTCAGTTTGTGCCGCTGACCAGCCTGCGGGTGCTGGACCTGTCCCACAA CAAGCTGGACCTGTATCACGGGCGCTCGTTCACGGAGCTGCCGCGCCTGG AAGCACTGGACCTCAGCTACAATAGCCAGCCCTTTACCATGCAGGGTGTG GGCCACAACCTCAGCTTCGTGGCCCAGCTGCCCGCCCTGCGCTACCTCAG CCTGGCGCACAATGACATCCATAGCCGAGTGTCCCAGCAGCTCTGTAGCG CCTCACTGTGCGCCCTGGACTTTAGCGGCAACGATCTGAGCCGGATGTGG GCTGAGGGAGACCTCTATCTCCGCTTCTTCCAAGGCCTAAGAAGCCTAGT CTGGCTGGACCTGTCCCAGAACCACCTGCACACCCTCCTGCCACGTGCCC TGGACAACCTCCCCAAAAGCCTGAAGCATCTGCATCTCCGTGACAATAAC CTGGCCTTCTTCAACTGGAGCAGCCTGACCCTCCTGCCCAAGCTGGAAAC CCTGGACTTGGCTGGAAACCAGCTGAAGGCCCTAAGCAATGGCAGCCTGC CATCTGGCACCCAGCTGCGGAGGCTGGACCTCAGTGGCAACAGCATCGGC TTTGTGAACCCTGGCTTCTTTGCCCTGGCCAAGCAGTTAGAAGAGCTCAA CCTCAGCGCCAATGCCCTCAAGACAGTGGAGCCCTCCTGGTTTGGCTCGA TGGTGGGCAACCTGAAAGTCCTAGACGTGAGCGCCAACCCTCTGCACTGT GCCTGTGGGGCGACCTTCGTGGGCTTCCTGCTGGAGGTACAGGCTGCCGT GCCTGGGCTGCCCAGCCGCGTCAAGTGTGGCAGTCCGGGGCAGCTCCAGG GCCATAGCATCTTTGCGCAAGACCTGCGCCTCTGCCTGGATGAGACCCTC TCGTGGAACTGTTTTGGCATCTCGCTGCTGGCCATGGCCCTGGGCCTGGT TGTGCCCATGCTGCACCACCTCTGCGGCTGGGACCTCTGGTACTGCTTCC ACCTGTGCCTGGCCTGGCTGCCCCACCGAGGGCAGCGGCGGGGCGCAGAC GCCCTGTTCTATGATGCCTTCGTGGTCTTTGACAAAGCTCAGAGTGCTGT GGCCGACTGGGTGTACAACGAGCTGCGGGTGCAGCTGGAGGAGCGCCGTG GGCGCCGCGCACTGCGCCTGTGCCTGGAGGAGCGAGACTGGTTACCTGGC AAGACGCTCTTCGAGAACCTGTGGGCCTCAGTCTACAGCAGCCGCAAGAC CCTGTTTGTGCTGGCCCACACGGACCGTGTCAGCGGCCTCTTGCGTGCCA GTTTCCTGCTGGCCCAGCAGCGCCTGCTGGAGGACCGCAAGGACGTTGTA GTGCTGGTGATCCTGCGCCCCGATGCCTACCGCTCCCGCTACGTGCGGCT GCGCCAGCGCCTCTGCCGCCAGAGTGTCCTCCTCTGGCCCCACCAGCCCC GTGGGCAGGGCAGCTTCTGGGCCCAGCTGGGCACAGCCCTGACCAGGGAC AACCACCACTTCTATAACCGGAACTTCTGCCGGGGCCCCACGACAGCCGA ATAGCACTGAGTGACAGCCCAGTTGCCCCAGCCCCCCTGGATTTGCCTCT CTGCCTGGGGTGCCCCAACCTGCTTTGCTCAGCCACACCACTGCTCTGCT CCCTGTTCCCCACCCCACCCCCCAGCCTGGCATG MGPRCTLHPLSLLVQVTALAAALAQGRLPAFLPCELQPHGLVNCNWLFLK SVPHFSAAAPRANVTSLSLLSNRIHHLHDSDFVHLSSLRTLNLKWNCPPA GLSPMHFPCHMTIEPNTFLAVPTLEELNLSYNSITTVPALPDSLVSLSLS RTNILVLDPTHLTGLHALRYLYMDGNCYYKNPCQGALEVVPGALLGLGNL THLSLKYNNLTEVPRSLPPSLETLLLSYNHIVTLTPEDLANLTALRVLDV GGNCRRCDHARNPCRECPKDHPKLHSDTFSHLSRLEGLVLKDSSLYNLDT RWFRGLDRLQVLDLSENFLYDCITKTTAFQGLARLRSLNLSFNYHKKVSF AHLHLAPSFGHLRSLKELDMHGIFFRSLSETTLQPLVQLPMLQTLRLQMN FINQAQLSIFGAFPGLLYVDLSDNRISGAARPVAITREVDGRERVWLPSR NLAPRPLDTLRSEDFMPNCKAFSFTLDLSRNNLVTIQSEMFARLSRLECL RLSHNSISQAVNGSQFVPLTSLRVLDLSHNKLDLYHGRSFTELPRLEALD LSYNSQPFTMQGVGHNLSFVAQLPALRYLSLAHNDIHSRVSQQLCSASLC ALDFSGNDLSRMWAEGDLYLRFFQGLRSLVWLDLSQNHLHTLLPRALDNL PKSLKHLHLRDNNLAFFNWSSLTLLPKLETLDLAGNQLKALSNGSLPSGT QLRRLDLSGNSIGFVNPGFFALAKQLEELNLSANALKTVEPSWFGSMVGN LKVLDVSANPLHCACGATFVGFLLEVQAAVPGLPSRVKCGSPGQLQGHSI FAQDLRLCLDETLSWNCFGISLLAMALGLVVPMLHHLCGWDLWYCFHLCL AWLPHRGQRRGADALFYDAFVVFDKAQSAVADWVYNELRVQLEERRGRRA LRLCLEERDWLPGKTLFENLWASVYSSRKTLFVLAHTDRVSGLLRASFLL AQQRLLEDRKDVVVLVILRPDAYRSRYVRLRQRLCRQSVLLWPHQPRGQG SFWAQLGTALTRDNHHFYNRNFCRGPTTAE.

The translated sequence was aligned with the four porcine TLR9 full length cDNA sequences deposited in Genbank (September 2011, P1-181109-prot.pro, pig-TLR9-NM_(—)213958. pro, pig-TLR9-AK349013.pro, pig-TLR9-GU138029.pro, pig-TLR9-AY859728.pro). Alignment (ClustalW; DNAStar) of the five porcine TLR9 polypeptide sequences showed polymorphisms at 9 positions. In each case the translated sequence of our TLR9 clone (P1-181109-prot) conformed to the majority polypeptide sequence, and was identical to the translation of cDNA clone AY859728.

Therefore, it is concluded that a correct version of porine TLR9 has been cloned.

Example 3 Gene Cloning of Canine Toll-Like Receptor 9 (TLR-9)

Total RNA from canine lymph nodes and canine spleen was purchased from Zyagen and was used as source for TLR9 messenger RNA (mRNA). From the canine spleen or lymph node total RNA, first strand cDNA was synthesized, essentially as described by the supplier of the reverse transcriptase (Expand Reverse Transciptase, Roche).

Primer were designed for the polymerase chain reaction (PCR) amplification of canine TLR9 (Genbank NM_(—)001002998) from the start codon region to the stop codon (Canis-TLR9-for and Canis-TLR9-rev, see below). However, initial PCR experiments using canine lymph node and spleen first strand cDNA aiming at the amplification of the full length product (expected: ˜3100 bp) proved to be repeatedly negative. Therefore, it was decided to prepare two overlapping TLR9 gene sections, that were more amenable for a PCR approach, in preparation for a PCR overlap extension approach. To this end primers were designed to yield a 5′-PCR canine TLR9 product with ˜1600 bp (Canis-TLR9-for and CanTLR9olr, see below), and a 3′-PCR canine TLR9 product with ˜1700 bp (CanTLR9olf and Canis-TLR9-rev).

Primer Sequences:

Canis-TLR9-for GAAGCTTACCATGGGCCCCTGCCGTGGCGCCCTGCA Canis-TLR9-rev GTCTAGATGATCAGGCTGTCGTGGGGCCCCGGCAGA CanTLR9olf TCACCTTGGACCTGTCTCGGAACAACC CanTLR9olr ACAGGTCCAGCTTGTTATGGGACAGG

PCR reactions (Expand High Fidelity PCR kit, Roche) were performed, the corresponding PCR products were agarose gel-purified, cloned into pCR2.1-Topo (Invitrogen), and three clones each were sequenced to identify PCR error-free versions, by comparing their translation products to each other, and to the database sequences NM_(—)00102998 and AY859723. These (pCR2.1-Topo-canTLR9-Nterm and pCR2.1-Topo-canTLR9-Cterm) were then used to join the 5′ and the 3′region of the canine TLR9 gene by an overlap extension approach. To this end inserts of pCR2.1-Topo-canTLR9-Nterm (primer: Canis-TLR9-for and CanTLR9olr) and pCR2.1-Topo-canTLR9-Cterm (primer: CanTLR9olf and Canis-TLR9-rev) were PCR amplified with only 9 cycles and a proof-reading polymerase (Phusion® Hot Start High-Fidelity DNA Polymerase, Thermo Scientific). The resulting PCR product were agarose gel purified, and then used combined in an overlap extension-PCR combination using the primer Canis-TLR9-for and Canis-TLR9-rev. The resulting ˜3100 bp PCR product was agarose gel purified and cloned into pCRBlunt-II (Invitrogen). Four independent clones were sequenced and one clone was chosen for further processing (pCR2.1-Topo-canineTLR9).

From this construct the insert was excised by HindIII/XbaI digestion, agarose gel-purified and subcloned into the HindIII/XbaI-cut mammalian expression vectors pcDNA3.1(neo) and pcDNA3.1(hyg) (both Invitrogen), yielding pcDNA3.1(neo)-canineTLR9 and pcDNA3.1(hyg)-canineTLR9, respectively. The corresponding inserts were resequenced (see below).

pcDNA3.1 insert sequence canine TLR9 (primer sequences underlined, start/stop codons highlighted bold)

AAGCTTACC

GGCCCCTGCCGTGGCGCCCTGCA CCCCCTGTCTCTCC TGGTGCAGGCTGCCGCGCTAGCCCTGGCCCTGGCCCAGGGCACCCTGCCT GCCTTCCTGCCCTGTGAGCTCCAGCCCCATGGCCTGGTGAACTGCAACTG GCTGTTCCTCAAGTCCGTGCCCCGCTTCTCGGCAGCTGCACCCCGCGGTA ACGTCACCAGCCTTTCCTTGTACTCCAACCGCATCCACCACCTCCATGAC TATGACTTTGTCCACTTCGTCCACCTGCGGCGTCTCAATCTCAAGTGGAA CTGCCCGCCCGCCAGCCTCAGCCCCATGCACTTTCCCTGTCACATGACCA TTGAGCCCAACACCTTCCTGGCTGTGCCCACCCTAGAGGACCTGAATCTG AGCTATAACAGCATCACGACTGTGCCCGCCCTGCCCAGTTCGCTTGTGTC CCTGTCCCTGAGCCGCACCAACATCCTGGTGCTGGACCCTGCCACCCTGG CAGGCCTTTATGCCCTGCGCTTCCTGTTCCTGGATGGCAACTGCTACTAC AAGAACCCCTGCCAGCAGGCCCTGCAGGTGGCCCCAGGTGCCCTCCTGGG CCTGGGCAACCTCACACACCTGTCACTCAAGTACAACAACCTCACCGTGG TGCCGCGGGGCCTGCCCCCCAGCCTGGAGTACCTGCTCTTGTCCTACAAC CACATCATCACCCTGGCACCTGAGGACCTGGCCAATCTGACTGCCCTGCG TGTCCTCGATGTGGGTGGGAACTGTCGCCGCTGTGACCATGCCCGTAACC CCTGCAGGGAGTGCCCCAAGGGCTTCCCCCAGCTGCACCCCAACACCTTC GGCCACCTGAGCCACCTCGAAGGCCTGGTGTTGAGGGACAGCTCTCTCTA CAGCCTGGACCCCAGGTGGTTCCATGGCCTGGGCAACCTCATGGTGCTGG ACCTGAGTGAGAACTTCCTGTATGACTGCATCACCAAAACCAAAGCCTTC TACGGCCTGGCCCGGCTGCGCAGACTCAACCTGTCCTTCAATTATCATAA GAAGGTGTCCTTTGCCCACCTGCATCTGGCATCCTCCTTCGGGAGCCTAC TGTCCCTGCAGGAGCTGGACATACATGGCATCTTCTTCCGCTCGCTCAGC GAGACCACGCTCCAGTCGCTGGCCCACCTGCCCATGCTCCAGCGTCTGCA TCTGCAGTTGAACTTTATCAGCCAGGCCCAGCTCAGCATCTTCGGCGCCT TCCCTGGCCTGCGGTACGTGGACTTGTCAGACAACCGCATCAGTGGAGCT GCAGAGCCCGCGGCTGCCACAGGGGAGGTAGAGGCGGACTGTGGGGAGAG AGTCTGGCCACAGTCCCGGGACCTTGCTCTGGGCACACTGGGCACCCCCG GCTCAGAGGCCTTCATGCCGAGCTGCAGGACCCTCAACTTCACCTTGGAC CTGTCTCGGAACAACCTAGTGACTGTTCAGCCGGAGATGTTTGTCCGGCT GGCGCGCCTCCAGTGCCTGGGCCTGAGCCACAACAGCATCTCGCAGGCGG TCAATGGCTCGCAGTTCGTGCCTCTGAGCAACCTGCGGGTGCTGGACCTG TCCCATAACAAGCTGGACCTGTACCACGGGCGCTCGTTCACGGAGCTGCC GCGGCTGGAGGCCTTGGACCTCAGCTACAACAGCCAGCCCTTCAGCATGC GGGGCGTGGGCCACAATCTCAGCTTTGTGGCACAGCTGCCAGCCCTGCGC TACCTCAGCCTGGCGCACAATGGCATCCACAGCCGCGTGTCCCAGCAGCT CCGCAGCGCCTCGCTCCGGGCCCTGGACTTCAGTGGCAATACCCTGAGCC AGATGTGGGCCGAGGGAGACCTCTATCTCCGCTTCTTCCAAGGCCTGAGA AGCCTGGTTCAGCTGGACCTGTCCCAGAATCGCCTGCATACCCTCCTGCC ACGCAACCTGGACAACCTCCCCAAGAGCCTGCGGCTCCTGCGGCTCCGTG ACAATTACCTGGCTTTCTTCAACTGGAGCAGCCTGGCCCTCCTACCCAAG CTGGAAGCCCTGGACCTGGCGGGAAACCAGCTGAAGGCCCTGAGCAATGG CAGCTTGCCCAACGGCACCCAGCTCCAGAGGCTGGACCTCAGCGGCAACA GCATCGGCTTCGTGGTCCCCGGCTTTTTTGCCCTGGCCGTGAGGCTTCGA GAGCTCAACCTCAGCGCCAACGCCCTCAAGACGGTGGAGCCCTCCTGGTT TGGTTCCCTGGCGGGTGCCCTGAAAGTCCTAGACGTGACCGCCAACCCCT TGCATTGCGCTTGCGGCGCAACCTTCGTGGACTTCTTGCTGGAGGTGCAG GCTGCGGTGCCCGGCCTGCCTAGCCGTGTCAAGTGCGGCAGCCCGGGCCA GCTCCAGGGCCGCAGCATCTTCGCACAGGACCTGCGCCTCTGCCTGGACG AAGCGCTCTCCTGGGTCTGTTTCAGCCTCTCGCTGCTGGCTGTGGCCCTG AGCCTGGCTGTGCCCATGCTGCACCAGCTCTGTGGCTGGGACCTCTGGTA CTGCTTCCACCTGTGCCTGGCCTGGCTGCCCCGGCGGGGGCGGCGGCGGG GTGTGGATGCCCTGGCCTACGACGCCTTCGTGGTCTTCGACAAGGCGCAG AGCTCGGTGGCGGACTGGGTGTACAATGAGCTGCGGGTACAGCTAGAGGA GCGCCGTGGGCGCCGGGCGCTACGCCTGTGTCTGGAGGAACGTGACTGGG TACCCGGCAAAACCCTCTTCGAGAACCTCTGGGCCTCAGTTTACAGCAGC CGCAAGACGCTGTTTGTGCTGGCCCGCACGGACAGAGTCAGCGGCCTCCT GCGTGCCAGCTTCCTGCTGGCCCAACAGCGCCTGCTGGAGGACCGCAAGG ACGTCGTGGTGCTGGTGATCCTGTGCCCCGACGCCCACCGCTCCCGCTAT GTGCGGCTGCGCCAGCGCCTCTGCCGCCAGAGTGTCCTCCTCTGGCCCCA CCAGCCCAGTGGCCAGCGCAGCTTCTGGGCCCAGCTGGGCACGGCCCTGA CCAGGGACAACCGCCACTTCTACAACCAGAACTTCTGCCGGGGCCC CACG ACAGCC

TCATCTA MGPCRGALHPLSLLVQAAALALALAQGTLPAFLPCELQPHGLVNCNWLFL KSVPRFSAAAPRGNVTSLSLYSNRIHHLHDYDFVHFVHLRRLNLKWNCPP ASLSPMHFPCHMTIEPNTFLAVPTLEDLNLSYNSITTVPALPSSLVSLSL SRTNILVLDPATLAGLYALRFLFLDGNCYYKNPCQQALQVAPGALLGLGN LTHLSLKYNNLTVVPRGLPPSLEYLLLSYNHIITLAPEDLANLTALRVLD VGGNCRRCDHARNPCRECPKGFPQLHPNTFGHLSHLEGLVLRDSSLYSLD PRWFHGLGNLMVLDLSENFLYDCITKTKAFYGLARLRRLNLSFNYHKKVS FAHLHLASSFGSLLSLQELDIHGIFFRSLSETTLQSLAHLPMLQRLHLQL NFISQAQLSIFGAFPGLRYVDLSDNRISGAAEPAAATGEVEADCGERVWP QSRDLALGTLGTPGSEAFMPSCRTLNFTLDLSRNNLVTVQPEMFVRLARL QCLGLSHNSISQAVNGSQFVPLSNLRVLDLSHNKLDLYHGRSFTELPRLE ALDLSYNSQPFSMRGVGHNLSFVAQLPALRYLSLAHNGIHSRVSQQLRSA SLRALDFSGNTLSQMWAEGDLYLRFFQGLRSLVQLDLSQNRLHTLLPRNL DNLPKSLRLLRLRDNYLAFFNWSSLALLPKLEALDLAGNQLKALSNGSLP NGTQLQRLDLSGNSIGFVVPGFFALAVRLRELNLSANALKTVEPSWFGSL AGALKVLDVTANPLHCACGATFVDFLLEVQAAVPGLPSRVKCGSPGQLQG RSIFAQDLRLCLDEALSWVCFSLSLLAVALSLAVPMLHQLCGWDLWYCFH LCLAWLPRRGRRRGVDALAYDAFVVFDKAQSSVADWVYNELRVQLEERRG RRALRLCLEERDWVPGKTLFENLWASVYSSRKTLFVLARTDRVSGLLRAS FLLAQQRLLEDRKDVVVLVILCPDAHRSRYVRLRQRLCRQSVLLWPHQPS GQRSFWAQLGTALTRDNRHFYNQNFCRGPTTA.

The translated sequence was aligned with the two canine TLR9 full length cDNA sequences deposited in Genbank (September 2011, P1-010709-prot.pro, TLR-9-NM_(—)001002998. pro, TLR-9-AY859723.pro). Alignment (ClustalW; DNAStar) of the three canine TLR9 polypeptide sequences showed polymorphisms at 8 positions. Except for one position (T459 in our sequence, P459 in the two database sequences) all polymorphic positions in our TLR9 clone (P1-010709-prot) conformed to either NM_(—)00102998 or AY859723. T459 has been confirmed in four independent PCR products from dog lymph node and spleen cDNA suggesting that this corresponds to the genotype of the donor dog.

Therefore, it is concluded that a correct version of canine TLR9 has been cloned.

Example 4 Madine-Darby Canine Kidney Cells as NF-κB Activation Reporter Cells

Madine-Darby canine kidney (MDCK) cells were obtained from ATCC that were maintained in MEM, lx non-essential amino acids, 8% (v/v) iFCS. Testing of spent growth medium for presence of secreted alkaline phosphatase activity was negative, a prerequisite for the use of this cell line in reporter gene assays.

As a first step, it was planned to transfect the MDCK cells with pNifTy2-SEAP (Invivogen), a plasmid containing a secreted alkaline phosphatase (SEAP) reporter gene under the control of NF-κB binding sites, and a zeocin resistance gene as selection marker. The inventor's studies showed, however, that MDCK cells are largely resistant to zeocin (up to the mg/ml range) precluding the use of pNifTy2-SEAP. Therefore, it was decided to generate ‘pNifTy-hyg-SEAP’ by replacing the CMV promoter region and parts of the polylinker (Nru I/Xba I digest of the plasmid and agarose gel isolation of the large fragment) in pcDNA3.1(hyg) by the Swa I/NheI fragment containing the NF-κB binding sites and the SEAP gene of pNifTy2-SEAP. Thereby, presence of the reporter gene cassette could now be selected for by addition of hygromycin to the medium, a cytostatic that is effective on MDCK cell.

MDCK cells were transfected with pNifTy-hyg-SEAP, selection pressure was applied (300 μg/ml hygromycin) and a resistant line was selected by repeated subculture in selection medium. The selected cell line was tested for SEAP induction by human tumor necrosis factor (huTNF-α,

positive control for proper functioning of the NF-κB pathway and reporter gene activation) as well as by a selection of pathogen-associated molecular patterns (PAMPs, such as E. coli lipopolysaccharide (LPS, TLR4), poly-I/polyC (double-stranded RNA, TLR3), muramyl dipeptide (MDP, NOD2), PAM₃CysSK₄ (a synthetic lipopeptide, TLR1/2), and R-848 (a low molecular weight agonist of TLR7). The results are shown in FIGS. 1 and 2 (FIG. 2 is a y-axis expansion of FIG. 1).

huTNF-α potently induces SEAP production in a polyclonal MDCK-pNifTy-hyg-SEAP cell line, a second prerequisite for the use of this cell line in reporter gene assays. PAMPs addressing 5 different pattern recognition receptors feeding into the NF-κB pathway showed low or no SEAP induction, which suggests that our MDCK-pNifTy-hyg-SEAP cell line expresses none or very few copies of the corresponding receptors, a third prerequisite for the use of this cell line in reporter gene assays. The highest background (albeit still very low) was seen with dsRNA, followed by MDP, while LPS, PAM₃CysSK₄ and R-848 showed virtually none.

These results prompted the inventors to perform single cell cloning of the MDCK-pNifTy-hyg-SEAP cell line, to stabilize the properties seen in the polyclonal line and to identify a superior clone. 46 clones were selected by limiting dilution in 96 well plates, and following expansion, they were stimulated with huTNF-α to identify the clones with the highest NF-κB-induced SEAP production capacity (see FIG. 3).

Example 5 Generation of Canine, Porcine and Bovine TLR9-21 Fusion Constructs and Subcloning into Expression Vector pIRES-Puro

A fusion construct encoding the extracellular domain of bovine TLR9 and intracellular domain of chicken TLR21 was created using a “PCR-sewing” protocol.

“PCR-sewing” entails three steps (see FIG. 4): first, complementary sequences are added by PCR to DNA fragments that should be fused into one construct. Secondly, the two fragments having complementary sequences are combined in a PCR-reaction without addition of primers. The complementary sequences enable the fragments to anneal and prime the elongation reaction by DNA polymerase. In the third PCR step, primers annealing to the 5′ and 3′ end of the chimeric molecule are added to amplify the fusion molecule.

The sequence encoding the extracellular domain of bovine TLR9 was amplified from the pcDNA3.1(neo)-bovine TLR9 construct (section 1) by PCR, the sequence encoding the transmembrane and intracellular domain of chicken TLR21 was amplified from pcDNA3.1(neo)-chicken TLR21 (sequences below). Complementary sequences were added to the 3′ end of the extracellular (TLR9) fragment and the 5′ end of the TLR21 fragment using primers with a 5′ overhang (sequences below) by PCR. Expand High Fidelity PCR kit (Roche) was used for all PCRs.

pcDNA3.1(neo)-chicken TLR21 insert sequence, start/stop codons highlighted bold.

AAGCTTACCATGATGGAGACAGCGGAGAAGGCATGGCCCAGCACCAGGAT GTGCCCCTCCCACTGCTGTCCACTCTGGCTGCTGCTGCTGGTGACAGTGA CACTGATGCCGATGGTGCACCCGTATGGCTTTCGCAACTGCATTGAGGAT GTCAAGGCACCTTTGTACTTCCGCTGCATCCAGCGCTTCCTGCAGTCGCC GGCCCTGGCAGTGTCTGACCTGCCACCACATGCCATCGCGCTCAATCTGT CATACAACAAAATGCGCTGCCTGCAGCCCTCTGCCTTTGCCCACCTGACA CAGCTGCATACCCTGGACCTGACCTACAACCTCCTGGAGACCCTCTCCCC TGGTGCCTTCAATGGGCTGGGTGTGCTGGTGGTGCTGGACCTGTCTCACA ACAAGCTGACCACACTTGCTGAAGGGGTGTTCAACAGCTTGGGCAACCTG TCCTCGCTGCAGGTACAACATAACCCCCTCAGCACGGTGTCACCAAGTGC TCTGCTACCCCTGGTCAACCTGCGCCGCCTGTCTCTACGGGGCGGGCGGC TGAATGGGTTGGGGGCAGTGGCAGTGGCAGTGCAGGGCTTGGCACAGCTG GAGCTGTTGGACCTATGTGAAAACAACCTGACAACGCTGGGGCCAGGCCC ACCGCTACCCGCCTCGCTGCTCACCCTGCAGCTGTGCAACAACTCGCTGA GGGAGTTAGCGGGGGGCAGCCCGGAGATGCTATGGCACGTGAAGATACTC GACCTCTCCTACAACAGTATCTCACAGGCGGAGGTCTTCACCCAGCTCCA CCTGCGCAACATCAGCCTGCTCCACCTGATCGGCAACCCCTTGGATGTCT TCCACCTGTTGGACATCTCTGACATCCAACCTCGCAGCCTGGATTTCTCT GGGTTGGTGCTGGGGGCTCAGGGGCTGGATAAGGTGTGCCTGAGGCTGCA GGGTCCCCAGGCCTTGCGGCGGCTGCAGCTACAACGCAACGGGCTGAAGG TGCTGCATTGTAATGCACTGCAGTTGTGTCCTGTGCTGAGAGAGCTGGAC CTGTCCTGGAACCGGCTACAGCACGTGGGCTGTGCCGGCCGGCTGCTGGG CAAGAAGCAGCGGGAGAAGCTGGAAGTGCTGACAGTGGAACACAACCTGC TGAAGAAACTGCCGTCTTGCCTGGGGGCCCAGGTGCTGCCTCGGCTGTAC AACATTTCCTTCCGCTTTAACCGCATCCTGACTGTTGGGCCCCAAGCCTT TGCCTACGCCCCGGCCCTGCAGGTGTTGTGGCTCAATATTAACAGCCTGG TGTGGCTGGACAGGCAGGCACTGTGGAGGCTGCACAACCTGACAGAGCTG CGCCTGGACAACAACCTGCTGACCGACCTCTATCACAACTCCTTCATTGA CCTCCACAGACTGCGCACCCTCAACCTGCGCAACAACCGTGTCTCCGTCC TCTTCTCTGGTGTCTTCCAGGGGCTGGCTGAGCTGCAGACGCTGGATTTA GGGGGCAACAACTTGCGCCACCTGACTGCACAGTCACTGCAGGGGCTGCC CAAACTGCGCAGGCTGTACCTGGACCGCAACAGATTGCTGGAGGTGAGCA GCACTGTGTTCGCCCCAGTGCAGGCTACCCTGGGGGTGCTGGACCTGCGG GCCAACAACCTGCAGTACATCTCACAGTGGCTGCGCAAGCCGCCACCCTT CCGCAACCTGAGCAGCCTGTACGACCTGAAGCTGCAGGCGCAGCAGCCCT ATGGACTGAAGATGCTGCCTCACTACTTCTTCCAGGGCTTGGTGAGGCTG CAGCAGCTGTCGCTGTCACAGAACATGCTGCGGTCCATCCCACCGGATGT CTTCGAGGACTTGGGCCAGCTGCGCTCCCTGGCATTGGCTGACAGCAGCA ATGGGCTGCATGACCTGCCTGACGGCATCTTCAGAAACCTGGGCAACCTG CGGTTCCTGGACCTGGAGAATGCAGGGCTGCACTCGCTCACTCTGGAAG TCTTCGGCAATCTCAGCCGGCTGCAGGTGCTGCACTTGGCCAGAAACGA GCTGAAGACCTTCAATGACAGCGTTGCCAGCCGGCTGTCCTCCTTGCGC TACCTGGACCTGCGCAAGTGTCCGCTCAGCTGCACCTGTGACAACATGT GGCTGCAGGGCTGGCTGAACAACAGCCGTGTGCAGGTTGTCTACCCCTA CAACTACACCTGTGGCTCACAGCACAATGCCTACATCCACAGCTTTGAC ACACACGTCTGCTTCCTGGACCTGGGGCTCTATCTCTTTGCTGGGACTG CACCGGCAGTGCTGCTGCTGCTGGTGGTGCCGGTGGTGTACCACCGCGCC TACTGGAGGCTGAAGTACCACTGGTACCTTCTGCGGTGCTGGGTCAACCA GCGGTGGCGGCGGGAGGAAAAGTGCTACCTCTATGACAGCTTTGTGTCCT ACAATTCAGCTGATGAAAGTTGGGTGTTGCAGAAGCTGGTGCCTGAGCTG GAGCACGGTGCCTTCCGCCTCTGCTTGCACCACCGCGACTTCCAGCCGGG CCGCAGCATCATTGACAACATTGTGGATGCTGTCTACAACAGCCGGAAGA CGGTGTGCGTGGTGAGCCGCAGCTACCTGCGCAGCGAGTGGTGCTCTCTA GAGGTGCAGTTGGCCAGCTACCGGCTGTTGGATGAGCGGCGTGACATCCT GGTACTGGTGCTGCTGGAGGACGTGGGTGATGCTGAGCTGTCTGCCTACC ACCGCATGCGGCGGGTGCTGCTGCGGCGCACCTACCTGCGCTGGCCTCTT GACCCCGCAGCTCAGCCGCTCTTTTGGGCACGGCTGAAGAGGGCACTGAG GTGGGGAGAGGGAGGAGAGGAGGAGGAAGAAGAAGGTTTGGGTGGAGGGA CGGGAAGGCCCAGGGAAGGAGACAAACAGATGTAGCGGCCGC Primers for bovine TLR9 (extracellular domain):

cowT9-chT21 5′Eco:  GCGGATATCACCATGGGCCCCTACTGTGC cowT9-chT21fusRV:  ATAGAGCCCCAGGTCCAGGAAGCAGAGGCGCAGGTCCTGTGT Primers for chicken TLR21 (transmembrane and intracellular domain):

cowT9-chT21fusFW:  ACACAGGACCTGCGCCTCTGCTTCCTGGACCTGGGGCTCTAT cowT9-chT21 3′ Eco:  GCGGAATTCCTACATCTGTTTGTCTCCTT.

The fusion product was cloned into pCRII-TOPO (Invitrogen) and one (1) clone was sequenced to examine if the sequence was PCR error-free. The sequence contained one (1) coding mutation which was corrected using the Quik Change II XL site directed mutagenesis kit from Stratagene and primers:

Mutagenesis Primers:

18-CowT9-chT21: CCAAGACCACCATCTTCAACGACCTGACCCAGCTGCGCAGACTCAACC 19-CowT9-chT21: GGTTGAGTCTGCGCAGCTGGGTCAGGTCGTTGAAGATGGTGGTCTTGG

After the mutagenesis procedure, multiple (5) clones were sequenced to examine if site-directed mutagenesis had been successful and did not introduce new mutations. A correct clone was used to redone the fusion construct into pIRESpuro3 (Clontech) using the primer-introduced EcoRI and EcoRV sites. The fusion construct in the resulting vector (pIRESpuro-bovTLR9-21) was resequenced (see below).

pIRESpuro-bovTLR9-21 insert sequence, (partial) primer sequence underlined, TLR21 (coding) sequences in italics, start/stop codons highlighted bold.

GATATCACCATGGGCCCCTACTGTGCCCCGCACCCCCTTTCTCTCCTGGTGCAGGCGGCGGCACTGGCAGC GGCCCTGGCCGAGGGCACCCTGCCTGCCTTCCTGCCCTGTGAGCTCCAGCCCCATGGTCAGGTGGACTGCA ACTGGCTGTTCCTGAAGTCTGTGCCGCACTTTTCGGCTGGAGCCCCCCGGGCCAATGTCACCAGCCTCTCC TTAATCTCCAACCGCATCCACCACTTGCATGACTCTGACTTCGTCCACCTGTCCAACCTGCGGGTCCTCAA CCTCAAGTGGAACTGCCCGCCGGCCGGCCTCAGCCCCATGCACTTCCCCTGCCGTATGACCATCGAGCCCA ACACCTTCCTGGCTGTGCCCACCCTGGAGGAGCTGAACCTGAGCTACAACGGCATCACGACCGTGCCTGCC CTGCCCAGTTCCCTCGTGTCCCTGTCGCTGAGCCACACCAGCATCCTGGTGCTAGGCCCCACCCACTTCAC CGGCCTGCACGCCCTGCGCTTTCTGTACATGGACGGCAACTGCTACTACATGAACCCCTGCCCGCGGGCCC TGGAGGTGGCCCCAGGCGCCCTCCTCGGCCTGGGCAACCTCACGCACCTGTCGCTCAAGTACAACAACCTC ACGGAGGTGCCCCGCCGCCTGCCCCCCAGCCTGGACACCCTGCTGCTGTCCTACAACCACATTGTCACCCT GGCACCCGAGGACCTGGCCAACCTGACTGCCCTGCGCGTGCTTGACGTGGGTGGGAACTGCCGCCGCTGCG ACCACGCCCGCAACCCCTGCAGGGAGTGCCCAAAGAACTTCCCCAAGCTGCACCCTGACACCTTCAGTCAC CTGAGCCGCCTCGAAGGCCTGGTGTTGAAGGACAGTTCTCTCTACAAACTAGAGAAAGATTGGTTCCGCGG CCTGGGCAGGCTCCAAGTGCTCGACCTGAGTGAGAACTTCCTCTATGACTACATCACCAAGACCACCATCT TCAACGACCTGACCCAGCTGCGCAGACTCAACCTGTCCTTCAATTACCACAAGAAGGTGTCCTTCGCCCAC CTGCACCTAGCGTCCTCCTTTGGGAGTCTGGTGTCCCTGGAGAAGCTGGACATGCACGGCATCTTCTTCCG CTCCCTCACCAACATCACGCTCCAGTCGCTGACCCGGCTGCCCAAGCTCCAGAGTCTGCATCTGCAGCTGA ACTTCATCAACCAGGCCCAGCTCAGCATCTTTGGGGCCTTCCCGAGCCTGCTCTTCGTGGACCTGTCGGAC AACCGCATCAGCGGAGCCGCGACGCCAGCGGCCGCCCTGGGGGAGGTGGACAGCAGGGTGGAAGTCTGGCG ATTGCCCAGGGGCCTCGCTCCAGGCCCGCTGGACGCCGTCAGCTCAAAGGACTTCATGCCAAGCTGCAACC TCAACTTCACCTTGGACCTGTCACGGAACAACCTGGTGACAATCCAGCAAGAGATGTTTACCCGCCTCTCC CGCCTCCAGTGCCTGCGCCTGAGCCACAACAGCATCTCGCAGGCGGTTAATGGCTCCCAGTTCGTGCCGCT GACCAGCCTGCGAGTGCTCGACCTGTCCCACAACAAGCTGGACCTGTACCATGGGCGCTCATTCACGGAGC TGCCGCAGCTGGAGGCACTGGACCTCAGCTACAACAGCCAGCCCTTCAGCATGCAGGGCGTGGGCCACAAC CTCAGCTTCGTGGCCCAGCTGCCCTCCCTGCGCTACCTCAGCCTTGCGCACAATGGCATCCACAGCCGCGT GTCACAGAAGCTCAGCAGCGCCTCGTTGCGCGCCCTGGACTTCAGCGGCAACTCCCTGAGCCAGATGTGGG CCGAGGGAGACCTCTATCTCTGCTTTTTCAAAGGCTTGAGGAACCTGGTCCAGCTGGACCTGTCCGAGAAC CATCTGCACACCCTCCTGCCTCGTCACCTGGACAACCTGCCCAAGAGCCTGCGGCAGCTGCGTCTCCGGGA CAATAACCTGGCCTTCTTCAACTGGAGCAGCCTGACCGTCCTGCCCCGGCTGGAAGCCCTGGATCTGGCAG GAAACCAGCTGAAGGCCCTGAGCAACGGCAGCCTGCCGCCTGGCATCCGGCTCCAGAAGCTGGACGTGAGC AGCAACAGCATCGGCTTCGTGATCCCCGGCTTCTTCGTCCGCGCGACTCGGCTGATAGAGCTTAACCTCAG CGCCAATGCCCTGAAGACAGTGGATCCCTCCTGGTTCGGTTCCTTAGCAGGGACCCTGAAAATCCTAGACG TGAGCGCCAACCCGCTCCACTGCGCCTGCGGGGCGGCCTTTGTGGACTTCCTGCTGGAGAGACAGGAGGCC GTGCCCGGGCTGTCCAGGCGCGTCACATGTGGCAGTCCGGGCCAGCTCCAGGGCCGCAGCATCTTCACACA GGACCTGCGCCTCTGCTTCCTGGACCTGGGGCTCTAT CTCTTTGCTGGGACTGCACCGGCAGTGCTGCTGC TGCTGGTGGTGCCGGTGGTGTACCACCGCGCCTACTGGAGGCTGAAGTACCACTGGTACCTTCTGCGGTGC TGGGTCAACCAGCGGTGGCGGCGGGAGGAAAAGTGCTACCTCTATGACAGCTTTGTGTCCTACAATTCAGC TGATGAAAGTTGGGTGTTGCAGAAGCTGGTGCCTGAGCTGGAGCACGGTGCCTTCCGCCTCTGCTTGCACC ACCGCGACTTCCAGCCGGGCCGCAGCATCATTGACAACATTGTGGATGCTGTCTACAACAGCCGGAAGACG GTGTGCGTGGTGAGCCGCAGCTACCTGCGCAGCGAGTGGTGCTCTCTAGAGGTGCAGTTGGCCAGCTACCG GCTGTTGGATGAGCGGCGTGACATCCTGGTACTGGTGCTGCTGGAGGACGTGGGTGATGCTGAGCTGTCTG CCTACCACCGCATGCGGCGGGTGCTGCTGCGGCGCACCTACCTGCGCTGGCCTCTTGACCCCGCAGCTCAG CCGCTCTTTTGGGCACGGCTGAAGAGGGCACTGAGGTGGGGAGAGGGAGGAGAGGAGGAGGAAGAAGAAGG TTTGGGTGGAGGGACGGGAAGGCCCAGGG AAGGAGACAAACAGATG

GAATTC MGPYCAPHPLSLLVQAAALAAALAEGTLPAFLPCELQPHGQVDCNWLFLKSVPHFSAGAPRANVTSLSLIS NRIHHLHDSDFVHLSNLRVLNLKWNCPPAGLSPMHFPCRMTIEPNTFLAVPTLEELNLSYNGITTVPALPS SLVSLSLSHTSILVLGPTHFTGLHALRFLYMDGNCYYMNPCPRALEVAPGALLGLGNLTHLSLKYNNLTEV PRRLPPSLDTLLLSYNHIVTLAPEDLANLTALRVLDVGGNCRRCDHARNPCRECPKNFPKLHPDTFSHLSR LEGLVLKDSSLYKLEKDWFRGLGRLQVLDLSENFLYDYITKTTIFNDLTQLRRLNLSFNYHKKVSFAHLHL ASSFGSLVSLEKLDMHGIFFRSLTNITLQSLTRLPKLQSLHLQLNFINQAQLSIFGAFPSLLFVDLSDNRI SGAATPAAALGEVDSRVEVWRLPRGLAPGPLDAVSSKDFMPSCNLNFTLDLSRNNLVTIQQEMFTRLSRLQ CLRLSHNSISQAVNGSQFVPLTSLRVLDLSHNKLDLYHGRSFTELPQLEALDLSYNSQPFSMQGVGHNLSF VAQLPSLRYLSLAHNGIHSRVSQKLSSASLRALDFSGNSLSQMWAEGDLYLCFFKGLRNLVQLDLSENHLH TLLPRHLDNLPKSLRQLRLRDNNLAFFNWSSLTVLPRLEALDLAGNQLKALSNGSLPPGIRLQKLDVSSNS IGFVIPGFFVRATRLIELNLSANALKTVDPSWFGSLAGTLKILDVSANPLHCACGAAFVDFLLERQEAVPG LSRRVTCGSPGQLQGRSIFTQDLRLCFLDLGLYLFAGTAPAVLLLLVVPVVYHRAYWRLKYHWYLLRCWVN QRWRREEKCYLYDSFVSYNSADESWVLQKLVPELEHGAFRLCLHHRDFQPGRSIIDNIVDAVYNSRKTVCV VSRSYLRSEWCSLEVQLASYRLLDERRDILVLVLLEDVGDAELSAYHRMRRVLLRRTYLRWPLDPAAQPLF WARLKRALRWGEGGEEEEEEGLGGGTGRPREGDKQM

Cloning of a Fusion Construct of the Extracellular Domain of Porcine TLR9 and the Transmembrane and Intracellular Domain of Chicken TLR21.

A fusion construct encoding the extracellular domain of porcine TLR9 and intracellular domain of chicken TLR21 was created using the “PCR-sewing” protocol as described above.

The sequence encoding the extracellular domain of porcine TLR9 from the pcDNA3.1(neo)-porcine TLR9 construct (described in Eample 2) was amplified by PCR as well as the sequence encoding the transmembrane and intracellular domain of chicken TLR21 from pcDNA3.1(neo)-chicken TLR21 (sequences above). Complementary sequences were added to the 3′end of the extracellular (TLR9) fragment and the 5′ end of the TLR21 fragment using primers with a 5′ overhang (sequences below) by PCR. Expand High Fidelity PCR kit (Roche) was used for all PCRs.

Primers for Porcine TLR9 (Extracellular Domain):

piT9-chT21 5′ E: GCGGAATTCCACCATGGGCCCCCGCTGCAC pigT9-chT21fusRV: ATAGAGCCCCAGGTCCAGGAAGCAGAGGCGCAGGTCTTGCGC

Primers for Chicken TLR21 (Transmembrane and Intracellular Domain):

pigT9-chT21fusFW: GCGCAAGACCTGCGCCTCTGCTTCCTGGACCTGGGGCTCTAT pig/dogT9-chT21-: GCGGCGGCCGCCTACATCTGTTTGTCTCCTT

The fusion product was cloned into pCRII-TOPO (Invitrogen) and one (1) clone was sequenced to examine if the sequence was PCR error-free. This clone was correct and was used to redone the fusion construct into pIRESpuro3 (Clontech) using primer-introduced EcoRI and NotI sites. The 5′ and 3′ ligation site of the fusion construct in pIRESpuro3 were sequenced to check the correct insertion of the fragment in the plasmid. The correct, resulting vector is pIRESpuro-porTLR9-21 (sequences below).

pIRESpuro-porTLR9-21 insert sequence, (partial) primer sequence underlined, TLR21 (coding) sequences in italics, start/stop codons highlighted bold.

GAATTCCACCATGGGCCCCCGCTGCACCCTGCACCCCCTTTCTCTCCTGGTGCAGGTGACAGCGCTGGCTG CGGCTCTGGCCCAGGGCAGGCTGCCTGCCTTCCTGCCCTGTGAGCTCCAGCCCCACGGCCTGGTGAACTGC AACTGGCTCTTCCTGAAGTCCGTGCCCCACTTCTCGGCGGCAGCGCCCCGGGCCAACGTCACCAGCCTCTC CTTACTCTCCAACCGCATCCACCACCTGCACGACTCTGACTTCGTCCACCTGTCCAGCCTACGAACTCTCA ACCTCAAGTGGAACTGCCCGCCGGCTGGCCTCAGCCCCATGCACTTCCCCTGCCACATGACCATCGAGCCC AACACCTTCCTGGCCGTGCCCACCCTGGAGGAGCTGAACCTGAGCTACAACAGCATCACGACCGTGCCTGC CCTGCCCGACTCCCTCGTGTCCCTGTCGCTGAGCCGCACCAACATCCTGGTGCTAGACCCCACCCACCTCA CTGGCCTACATGCCCTGCGCTACCTGTACATGGATGGCAACTGCTACTACAAGAACCCCTGCCAGGGGGCG CTGGAGGTGGTGCCGGGTGCCCTCCTCGGCCTGGGCAACCTCACACATCTCTCACTCAAGTACAACAATCT CACGGAGGTGCCCCGCAGCCTGCCCCCCAGCCTGGAGACCCTGCTGTTGTCCTACAACCACATTGTCACCC TGACGCCTGAGGACCTGGCCAATCTGACTGCCCTGCGCGTGCTTGATGTGGGGGGGAACTGCCGCCGCTGT GACCATGCCCGCAACCCCTGCAGGGAGTGCCCAAAGGACCACCCCAAGCTGCACTCTGACACCTTCAGCCA CCTGAGCCGCCTCGAAGGCCTGGTGTTGAAAGACAGTTCTCTCTACAACCTGGACACCAGGTGGTTCCGAG GCCTGGACAGGCTCCAAGTGCTGGACCTGAGTGAGAACTTCCTCTACGACTGCATCACCAAGACCACGGCC TTCCAGGGCCTGGCCCGACTGCGCAGCCTCAACCTGTCCTTCAATTACCACAAGAAGGTGTCCTTTGCCCA CCTGCACCTGGCACCCTCCTTTGGGCACCTCCGGTCCCTGAAGGAGCTGGACATGCATGGCATCTTCTTCC GCTCGCTCAGTGAGACCACGCTCCAACCTCTGGTCCAACTGCCTATGCTCCAGACCCTGCGCCTGCAGATG AACTTCATTAACCAGGCCCAGCTCAGCATCTTTGGGGCCTTCCCTGGCCTGCTGTACGTGGACCTATCGGA CAACCGCATCAGCGGAGCTGCAAGGCCAGTGGCCATTACTAGGGAGGTGGATGGTAGGGAGAGGGTCTGGC TGCCTTCCAGGAACCTCGCTCCACGTCCACTGGACACTCTCCGCTCAGAGGACTTCATGCCAAACTGCAAG GCCTTCAGCTTCACCTTGGACCTGTCTCGGAACAACCTGGTGACAATCCAGTCGGAGATGTTTGCTCGCCT CTCACGCCTCGAGTGCCTGCGCCTGAGCCACAACAGCATCTCCCAGGCGGTCAATGGCTCTCAGTTTGTGC CGCTGACCAGCCTGCGGGTGCTGGACCTGTCCCACAACAAGCTGGACCTGTATCACGGGCGCTCGTTCACG GAGCTGCCGCGCCTGGAAGCACTGGACCTCAGCTACAATAGCCAGCCCTTTACCATGCAGGGTGTGGGCCA CAACCTCAGCTTCGTGGCCCAGCTGCCCGCCCTGCGCTACCTCAGCCTGGCGCACAATGACATCCATAGCC GAGTGTCCCAGCAGCTCTGTAGCGCCTCACTGTGCGCCCTGGACTTTAGCGGCAACGATCTGAGCCGGATG TGGGCTGAGGGAGACCTCTATCTCCGCTTCTTCCAAGGCCTAAGAAGCCTAGTCTGGCTGGACCTGTCCCA GAACCACCTGCACACCCTCCTGCCACGTGCCCTGGACAACCTCCCCAAAAGCCTGAAGCATCTGCATCTCC GTGACAATAACCTGGCCTTCTTCAACTGGAGCAGCCTGACCCTCCTGCCCAAGCTGGAAACCCTGGACTTG GCTGGAAACCAGCTGAAGGCCCTAAGCAATGGCAGCCTGCCATCTGGCACCCAGCTGCGGAGGCTGGACCT CAGTGGCAACAGCATCGGCTTTGTGAACCCTGGCTTCTTTGCCCTGGCCAAGCAGTTAGAAGAGCTCAACC TCAGCGCCAATGCCCTCAAGACAGTGGAGCCCTCCTGGTTTGGCTCGATGGTGGGCAACCTGAAAGTCCTA GACGTGAGCGCCAACCCTCTGCACTGTGCCTGTGGGGCGACCTTCGTGGGCTTCCTGCTGGAGGTACAGGC TGCCGTGCCTGGGCTGCCCAGCCGCGTCAAGTGTGGCAGTCCGGGGCAGCTCCAGGGCCATAGCATCTTTG CGCAAGACCTGCGCCTCTGCTTCCTGGACCTGGGGCTCTA TCTCTTTGCTGGGACTGCACCGGCAGTGCTG CTGCTGCTGGTGGTGCCGGTGGTGTACCACCGCGCCTACTGGAGGCTGAAGTACCACTGGTACCTTCTGCG GTGCTGGGTCAACCAGCGGTGGCGGCGGGAGGAAAAGTGCTACCTCTATGACAGCTTTGTGTCCTACAATT CAGCTGATGAAAGTTGGGTGTTGCAGAAGCTGGTGCCTGAGCTGGAGCACGGTGCCTTCCGCCTCTGCTTG CACCACCGCGACTTCCAGCCGGGCCGCAGCATCATTGACAACATTGTGGATGCTGTCTACAACAGCCGGAA GACGGTGTGCGTGGTGAGCCGCAGCTACCTGCGCAGCGAGTGGTGCTCTCTAGAGGTGCAGTTGGCCAGCT ACCGGCTGTTGGATGAGCGGCGTGACATCCTGGTACTGGTGCTGCTGGAGGACGTGGGTGATGCTGAGCTG TCTGCCTACCACCGCATGCGGCGGGTGCTGCTGCGGCGCACCTACCTGCGCTGGCCTCTTGACCCCGCAGC TCAGCCGCTCTTTTGGGCACGGCTGAAGAGGGCACTGAGGTGGGGAGAGGGAGGAGAGGAGGAGGAAGAAG AAGGTTTGGGTGGAGGGACGGGAAGGCCCAGGG AAGGAGACAAACAGATG

GCGGCCGC MGPRCTLHPLSLLVQVTALAAALAQGRLPAFLPCELQPHGLVNCNWLFLKSVPHFSAAAPRANVTSLSLLS NRIHHLHDSDFVHLSSLRTLNLKWNCPPAGLSPMHFPCHMTIEPNTFLAVPTLEELNLSYNSITTVPALPD SLVSLSLSRTNILVLDPTHLTGLHALRYLYMDGNCYYKNPCQGALEVVPGALLGLGNLTHLSLKYNNLTEV PRSLPPSLETLLLSYNHIVTLTPEDLANLTALRVLDVGGNCRRCDHARNPCRECPKDHPKLHSDTFSHLSR LEGLVLKDSSLYNLDTRWFRGLDRLQVLDLSENFLYDCITKTTAFQGLARLRSLNLSFNYHKKVSFAHLHL APSFGHLRSLKELDMHGIFFRSLSETTLQPLVQLPMLQTLRLQMNFINQAQLSIFGAFPGLLYVDLSDNRI SGAARPVAITREVDGRERVWLPSRNLAPRPLDTLRSEDFMPNCKAFSFTLDLSRNNLVTIQSEMFARLSRL ECLRLSHNSISQAVNGSQFVPLTSLRVLDLSHNKLDLYHGRSFTELPRLEALDLSYNSQPFTMQGVGHNLS FVAQLPALRYLSLAHNDIHSRVSQQLCSASLCALDFSGNDLSRMWAEGDLYLRFFQGLRSLVWLDLSQNHL HTLLPRALDNLPKSLKHLHLRDNNLAFFNWSSLTLLPKLETLDLAGNQLKALSNGSLPSGTQLRRLDLSGN SIGFVNPGFFALAKQLEELNLSANALKTVEPSWFGSMVGNLKVLDVSANPLHCACGATFVGFLLEVQAAVP GLPSRVKCGSPGQLQGHSIFAQDLRLCFLDLGLYLFAGTAPAVLLLLVVPVVYHRAYWRLKYHWYLLRCWV NQRWRREEKCYLYDSFVSYNSADESWVLQKLVPELEHGAFRLCLHHRDFQPGRSIIDNIVDAVYNSRKTVC VVSRSYLRSEWCSLEVQLASYRLLDERRDILVLVLLEDVGDAELSAYHRMRRVLLRRTYLRWPLDPAAQPL FWARLKRALRWGEGGEEEEEEGLGGGTGRPREGDKQM

Cloning of a Fusion Construct of the Extracellular Domain of Canine TLR9 and the Transmembrane and Intracellular Domain of Chicken TLR21.

A fusion construct encoding the extracellular domain of canine TLR9 and intracellular domain of chicken TLR21 was created using the “PCR-sewing” protocol as described above. The sequence encoding the extracellular domain of canine TLR9 from the pcDNA3.1(neo)-canine TLR9 construct (described in example 3) was amplified by PCR as well as the sequence encoding the transmembrane and intracellular domain of chicken TLR21 from pcDNA3.1(neo)-chicken TLR21 (sequences above). Complementary sequences were added to the 3′end of the extracellular (TLR9) fragment and the 5′ end of the TLR21 fragment using primers with a 5′ overhang (sequences below) by PCR. Expand High Fidelity PCR kit (Roche) was used for all PCRs.

Primers for Canine TLR9 (Extracellular Domain):

doT9-chT21 5′ E: GCGGAATTCCACCATGGGCCCCTGCCGTGG dogT9-chT21fusRV: ATAGAGCCCCAGGTCCAGGAAGCAGAGGCGCAGGTCCTGTGC

Primers for Chicken TLR21 (Transmembrane and Intracellular Domain):

dogT9-chT21fusFW: GCACAGGACCTGCGCCTCTGCTTCCTGGACCTGGGGCTCTAT pig/dogT9-chT21-: GCGGCGGCCGCCTACATCTGTTTGTCTCCTT

The fusion product was cloned into pCRII-TOPO (Invitrogen) and one clone was sequenced to examine if the sequence was PCR error-free. The sequence contained one coding and one silent mutation. The coding mutation was corrected using the Quik Change II XL site directed mutagenesis kit (Stratagene) and primers:

Mutagenesis Primers:

dT9-chT21mt FW: GCAGGCTGCCGCGCTAGCCCTGGCCCTGGCCCAGGGC dT9-chT21mt RV: GCCCTGGGCCAGGGCCAGGGCTAGCGCGGCAGCCTGC

After the mutagenesis procedure, multiple (8) clones were sequenced to examine if site-directed mutagenesis had been successful. One clone contained the corrected nucleotide. This clone was used to redone the fusion construct into pIRESpuro3 (Clontech) using the primer-introduced EcoRI and the EcoRI site present in pCRII-TOPO. The resulting vector (pIRESpuro-canTLR9-21) was completely sequenced. Sequencing identified two silent mutations which do not affect the amino acid sequence. Therefore it was concluded that this clone could be used for further applications.

pIRESpuro-canTLR9-21 insert sequence, (partial) primer sequence underlined, TLR21 (coding) sequences in italics, start/stop codons highlighted bold.

GAATCCACCATGGGCCCCTGCCGTGGCGCCCTGCACCCCCTGTCTCTCCTGGTGCAGGCTGCCGCGCTAGC CCTGGCCCTGGCCCAGGGCACCCTGCCTGCCTTCCTGCCCTGTGAGCTCCAGCCCCATGGCCTGGTGAACT GCAACTGGCTGTTCCTCAAGTCCGTGCCCCGCTTCTCGGCAGCTGCACCCCGCGGTAACGTCACCAGCCTT TCCTTGTACTCCAACCGCATCCACCACCTCCATGACTATGACTTTGTCCACTTCGTCCACCTGCGGCGTCT CAATCTCAAGTGGAACTGCCCGCCCGCCAGCCTCAGCCCCATGCACTTTCCCTGTCACATGACCATTGAGC CCAACACCTTCCTGGCTGTGCCCACCCTAGAGGACCTGAATCTGAGCTATAACAGCATCACGACTGTGCCC GCCCTGCCCAGTTCGCTTGTGTCCCTGTCCCTGAGCCGCACCAACATCCTGGTGCTGGACCCTGCCACCCT GGCAGGCCTTTATGCCCTGCGCTTCCTGTTCCTGGATGGCAACTGCTACTACAAGAACCCCTGCCAGCAGG CCCTGCAGGTGGCCCCAGGTGCCCTCCTGGGCCTGGGCAACCTCACACACCTGTCACTCAAGTACAACAAC CTCACCGTGGTGCCGCGGGGCCTGCCCCCCAGCCTGGAGTACCTGCTCTTGTCCTACAACCACATCATCAC CCTGGCACCTGAGGACCTGGCCAATCTGACTGCCCTGCGTGTCCTCGATGTGGGTGGGAACTGTCGCCGCT GTGACCATGCCCGTAACCCCTGCAGGGAGTGCCCCAAGGGCTTCCCCCAGCTGCACCCCAACACCTTCGGC CACCTGAGCCACCTCGAAGGCCTGGTGTTGAGGGACAGCTCTCTCTACAGCCTGGACCCCAGGTGGTTCCA TGGCCTGGGCAACCTCATGGTGCTGGACCTGAGTGAGAACTTCCTGTATGACTGCATCACCAAAACCAAAG CCTTCTACGGCCTGGCCCGGCTGCGCAGACTCAACCTGTCCTTCAATTATCATAAGAAGGTGTCCTTTGCC CACCTGCATCTGGCATCCTCCTTCGGGAGCCTACTGTCCCTGCAGGAGCTGGACATACATGGCATCTTCTT CCGCTCGCTCAGCGAGACCACGCTCCAGTCGCTGGCCCACCTGCCCATGCTCCAGCGTCTGCATCTGCAGT TGAACTTTATCAGCCAGGCCCAGCTCAGCATCTTCGGCGCCTTCCCTGGCCTGCGGTACGTGGACTTGTCA GACAACCGCATCAGTGGAGCTGCAGAGCCCGCGGCTGCCACAGGGGAGGTAGAGGCGGACTGTGGGGAGAG AGTCTGGCCACAGTCCCGGGACCTTGCTCTGGGCACACTGGGCACCCCCGGCTCAGAGGCCTTCATGCCGA GCTGCAGGACCCTCAACTTCACCTTGGACCTGTCTCGGAACAACCTAGTGACTGTTCAGCCAGAGATGTTT GTCCGGCTGGCGCGCCTCCAGTGCCTGGGCCTGAGCCACAACAGCATCTCGCAGGCGGTCAATGGCTCGCA GTTCGTGCCTCTGAGCAACCTGCGGGTGCTGGACCTGTCCCATAACAAGCTGGACCTGTACCACGGGCGCT CGTTCACGGAGCTGCCGCGGCTGGAGGCCTTGGACCTCAGCTACAACAGCCAGCCCTTCAGCATGCGGGGC GTGGGCCACAATCTCAGCTTTGTGGCACAGCTGCCAGCCCTGCGCTACCTCAGCCTGGCGCACAATGGCAT CCACAGCCGCGTGTCCCAGCAGCTCCGCAGCGCCTCGCTCCGGGCCCTGGACTTCAGTGGCAATACCCTGA GCCAGATGTGGGCCGAGGGAGACCTCTATCTCCGCTTCTTCCAAGGCCTGAGAAGCCTGGTTCAGCTGGAC CTGTCCCAGAATCGCCTGCATACCCTCCTGCCACGCAACCTGGACAACCTCCCCAAGAGCCTGCGGCTCCT GCGGCTCCGTGACAATTACCTGGCTTTCTTCAACTGGAGCAGCCTGGCCCTCCTACCCAAGCTGGAAGCCC TGGACCTGGCGGGAAACCAGCTGAAGGCCCTGAGCAATGGCAGCTTGCCCAACGGCACCCAGCTCCAGAGG CTGGACCTCAGCGGCAACAGCATCGGCTTCGTGGTCCCCGGCTTTTTTGCCCTGGCCGTGAGGCTTCGAGA GCTCAACCTCAGCGCCAACGCCCTCAAGACGGTGGAGCCCTCCTGGTTTGGTTCCCTGGCGGGTGCCCTGA AAGTCCTAGACGTGACCGCCAACCCCTTGCATTGCGCTTGCGGCGCAACCTTCGTGGACTTCTTGCTGGAG GTGCAGGCTGCGGTGCCCGGCCTGCCTAGCCGTGTCAAGTGCGGCAGCCCGGGCCAGCTCCAGGGCCGCAG CATCTTCGCACAGGACCTGCGCCTCTGCTTCCTGGACCTGGGGCTCTAT CTCTTTGCTGGGACTGCACCGG CAGTGCTGCTGCTGCTGGTGGTGCCGGTGGTGTACCACCGCGCCTACTGGAGGCTGAAGTACCACTGGTAC CTTCTGCGGTGCTGGGTCAACCAGCGGTGGCGGCGGGAGGAAAAGTGCTACCTCTATGACAGCTTTGTGTC CTACAATTCAGCTGATGAAAGTTGGGTGTTGCAGAAGCTGGTGCCTGAGCTGGAGCACGGTGCCTTCCGCC TCTGCTTGCACCACCGCGACTTCCAGCCGGGCCGCAGCATCATTGACAACATTGTGGATGCTGTCTACAAC AGCCGGAAGACGGTGTGCGTGGTAAGCCGCAGCTACCTGCGCAGCGAGTGGTGCTCTCTAGAGGTGCAGTT GGCCAGCTACCGGCTGTTGGATGAGCGGCGTGACATCCTGGTACTGGTGCTGCTGGAGGACGTGGGTGATG CTGAGCTGTCTGCCTACCACCGCATGCGGCGGGTGCTGCTGCGGCGCACCTACCTGCGCTGGCCTCTTGAC CCCGCAGCTCAGCCGCTCTTTTGGGCACGGCTGAAGAGGGCACTGAGGTGGGGAGAGGGAGGAGAGGAGGA GGAAGAAGAAGGTTTGGGTGGAGGGACGGGAAGGCCCAGGG AAGGAGACAAACAGATG

GCGGCCGC MGPCRGALHPLSLLVQAAALALALAQGTLPAFLPCELQPHGLVNCNWLFLKSVPRFSAAAPRGNVTSLSLY SNRIHHLHDYDFVHFVHLRRLNLKWNCPPASLSPMHFPCHMTIEPNTFLAVPTLEDLNLSYNSITTVPALP SSLVSLSLSRTNILVLDPATLAGLYALRFLFLDGNCYYKNPCQQALQVAPGALLGLGNLTHLSLKYNNLTV VPRGLPPSLEYLLLSYNHIITLAPEDLANLTALRVLDVGGNCRRCDHARNPCRECPKGFPQLHPNTFGHLS HLEGLVLRDSSLYSLDPRWFHGLGNLMVLDLSENFLYDCITKTKAFYGLARLRRLNLSFNYHKKVSFAHLH LASSFGSLLSLQELDIHGIFFRSLSETTLQSLAHLPMLQRLHLQLNFISQAQLSIFGAFPGLRYVDLSDNR ISGAAEPAAATGEVEADCGERVWPQSRDLALGTLGTPGSEAFMPSCRTLNFTLDLSRNNLVTVQPEMFVRL ARLQCLGLSHNSISQAVNGSQFVPLSNLRVLDLSHNKLDLYHGRSFTELPRLEALDLSYNSQPFSMRGVGH NLSFVAQLPALRYLSLAHNGIHSRVSQQLRSASLRALDFSGNTLSQMWAEGDLYLRFFQGLRSLVQLDLSQ NRLHTLLPRNLDNLPKSLRLLRLRDNYLAFFNWSSLALLPKLEALDLAGNQLKALSNGSLPNGTQLQRLDL SGNSIGFVVPGFFALAVRLRELNLSANALKTVEPSWFGSLAGALKVLDVTANPLHCACGATFVDFLLEVQA AVPGLPSRVKCGSPGQLQGRSIFAQDLRLCFLDLGLYLFAGTAPAVLLLLVVPVVYHRAYWRLKYHWYLLR CWVNQRWRREEKCYLYDSFVSYNSADESWVLQKLVPELEHGAFRLCLHHRDFQPGRSIIDNIVDAVYNSRK TVCVVSRSYLRSEWCSLEVQLASYRLLDERRDILVLVLLEDVGDAELSAYHRMRRVLLRRTYLRWPLDPAA QPLFWARLKRALRWGEGGEEEEEEGLGGGTGRPREGDKQM

Example 6 Transfection of MDCK-pNifTyhyg-SEAP with Canine TLR9-21 Fusion Constructs a) Transfection and Selection of Clones

To investigate the potential of MDCK-pNiffyhyg-SEAK-clone15 for the expression and detection of TLR9-21 fusion constructs, this clonal cell line was transfected with pIRES-puro-canineTLR9-21. Transfectants were selected by repeated passage with medium supplemented with 300 μg/ml hygromycin and 8 μg/ml puromycin. Testing of the resulting polyclonal cell line with the standard oligonucleotide ODN-2006-PTO indicated induction of SEAP secretion. Single cell cloning was performed and 54 clones were expanded for further testing with ODN-2006-PTO (see graph below). A large number of clones were identified that showed induction of massive amounts of SEAP. Four clones with the best signal-to-noise ratio (No 17, 23, 32 and 40) were chosen for expansion and to generate frozen stabilates. After retesting, clone No 17 was selected for further experiments (See FIG. 5).

b) MDCK-pNiffyhyg-SEAP-pIRESpuro-canTLR9-21-Clone 17: Testing of the Stimulatory Activity of Oligonucleotides Experiment 1:

A series of phosphorothioate oligonucleotides (PTO-ODNs, thio5-4 up to thio 5-10) was tested, together with the standard oligonucleotides from human medicine, 2006-PTO and 2007-PTO

V_(max) EC₅₀ _((mOD/min/) (nM) _(20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.3 311 2007-PTO tcgtcgttgtcgttttgtcgtt 8.6 325 thio5-4 gtcgtcgtcgtc >250 n.d. thio5-5 gtcgtcgtcgtcgtc 80.6 348 thio5-6 gtcgtcgtcgtcgtcgtc 23.6 319 thio5-7 gtcgtcgtcgtcgtcgtcgtc 7.2 300 thio5-8 gtcgtcgtcgtcgtcgtcgtcgtc 7.8 308 thio5-10  gtcgtcgtcgtcgtcgtcgtcgtc 4.3 296 gtcgtc

From this experiments, it can be deduced that the pIRESpuro-canTLR9-21-expressing MDCK-pNifTyhyg cell line that was generated is capable of defining different potencies via the calculation of EC₅₀ values (see FIG. 6).

It can be shown that for immunostimulatory ODNs, with structure elements such as gtcgtc, the number of cg elements is important: 9>7>6>5>>4>>3 (see table above). This experiment also immediately outlines the potential of this cell line for generation of structure-activity relationships (SAR) and lead optimization of immunostimulatory ODNs.

It was also shown that PTO-ODNs (2006-PTO and 2007-PTO) known from human research are highly potent on the canine TLR9-21 fusion protein, but at least one candidate (thio5-10) of the inventor's initial ‘lead optimization’ proved to be as potent or slightly more potent on canine TLR9-21 fusion that these human standard ODNs.

Experiment 2:

A series of phosphodiester oligonucleotides (10 PDE-ODNs), that had proven to be highly potent on chicken TLR21 (the donor of the fusion part) were tested on canine TLR9-21 fusion, together with the standard oligonucleotide from human medicine, 2006-PTO (see FIG. 7).

Result:

None of the 10 PDE-ODNs showed any SEAP-inducing activity in the test range (500 nM-3.9 nM), while 2006-PTO showed an EC₅₀ of ˜4 nM, the expected range for this ODN.

Interpretation:

the recognition of ODNs is dictated by the N-terminal fusion portion (in this case canine TLR9). There is a dramatic species specificity of PDE-ODN recognition, since the tested ODNs show single digit nM or even pM EC₅₀ values on chicken TLR21, while 2006-PTO is less potent on this receptor (31 nM) than on canine TLR9-21 fusion.

Experiment 3:

Here an experiment was performed on PTO-ODNs that have been used in the literature in the human and mouse context: 1668-PTO, 2216-PTO and 2395-PTO.

Vmax EC₅₀ _((mOD/min/) (nM) _(20 ul)) 1668-PTO tccatgacgttcctgatgct 22.5 363 2216-PTO gggggacgatcgtcgggggg 30.6 161 2395-PTO tcgtcgttttcggcgcgcgccg 47.1 201

All three PTO-ODNs are active on canine TLR9-21 fusion with double digit nM EC₅₀ values. However, with respect to maximally attainable stimulation of SEAP production (V_(max)) the potency order is 1668>2395>2216 (see FIG. 8). Remarkable, testing of the same ODNs on chicken TLR21 shows that 2216-PTO is inactive, 1668-PTO has an EC₅₀ of ˜1000 nM, and only 2395-PTO has some potency in showing an EC₅₀ of 39.4 nM.

Experiment 4:

A ‘lead optimization’ was attempted based on what could possibly be active elements form the published oligonucleotides 1668-PTO, 2216-PTO and 2395-PTO. These active elements are underlined and/or in Italic in the parental ODN and then arranged in repeats in the mod1/2 ODNs:

V_(max) EC₅₀ _((mOD/min/) (nM) _(20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.3 311 1668-PTO tccat gacgtt cctgatgct 22.5 363 1668-mod1 gacgttgacgttgacgttgacgtt 5.7 312 1668-mod2 tgacgttctgacgttctgacgttctgacgt 4.9 273 tc 2216-PTO gggggacgatcgtcgggggg 30.6 161 2216-mod1 gacgatcgtcgacgatcgtc 19.0 309 2216-mod2 gacgatcgtcgacgatcgtcgacgatcgtc 7.9 293 2395-PTO tcgtcgttttcggcgcgcgccg 47.1 201 2395-mod1 tcgtcgttttcgtcgtcgttttcg 7.1 299 2395-mod2 tcgtcgttttcgtcgtcgttttcgtcgtcg 3.7 258 ttttcg

Based on the EC₅₀ values the ‘lead optimization’ has proven to be successful. In all three cases, the mod1/2 PTO-ODN versions were more potent than their parental PTO ODN. In the case of 2216-PTO and 2395-PTO in addition a significant increase in V_(max) was visible. Five out of six newly designed PTO-ODNs are within the activity region of the paradigmal 2006-PTO (see FIG. 9).

Experiment 5:

A ‘lead optimization’ based on possible active elements was tried for the published oligonucleotide 2007-PTO.

V_(max) EC₅₀ _((mOD/min/) (nM) _(20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.3 311 2007-PTO tcgtcgttgtcgttttgtcgtt 8.6 325 2007-mod1 tcgtcgttgtcgttttgtcgttgtcgtt 6.0 299 2007-mod2 tcgtcgtcgtcgttgtcgttttgtcgtt 6.1 306 2007-mod3 tcgtcgtcgtcgttgtcgttttgtcgtt 6.6 295 gtcgtt 2007-dimer tcgtcgttgtcgttttgtcgtttcgtcg 4.1 293 ttgtcgttttgtcgtt

The addition of cg-containing elements to the 5′-end or 3′-end or both, as well as dimerization of 2007-PTO did not lead to an improvement of activity (both with respect to EC₅₀ and V_(max)), but neither did it lead to a loss of activity. The single digit nanomolar activity is preserved. None of the listed ODNs has been reported in the literature so far (see FIG. 10).

Experiment 6:

Here two PTO-ODNs were tested that are mentioned in the literature (ODN-17 and ODN-Ling1). Also was tested the impact of replacement of the complete (thio5-8pde2A) and partial (thio5-8pde2B) phosphorothioate bonds of the CpG elements in thio5-8. Furthermore, multimers of the immunomodulatoy element -ttcgtc- were tested.

EC₅₀ V_(max (mOD/) (nM) _(min/20) _(ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.3 311 thio5-8 gtcgtcgtcgtcgtcgtcgtcgtc 7.0 276 thio5- gtCGtCGtCGtCGtCGtCGtCGtc >100 n.d. 8pde2A thio5- gtCGtcgtCGtcgtCGtcgtCGtc 61.0 268 8pde2B thio9-3 ttcgtcttcgtcttcgtc 47.0 327 thio9-5 ttcgtcttcgtcttcgtcttcgtc 8.9 248 ttcgtc ODN-17 gtcgttgtcgttgtcgtt 43.4 374 ODN-Ling1 tcgacgtttgacgtttgacgtt 8.2 359

It has been reported in the literature that replacement of PTO by PDE bonds within the CpG elements sometimes boosts stimulatory activity of PTO-ODNs. This idea was tested with thio5-8. In the inventor's hands the PDE-modified versions were far less active on canine TLR9-21 fusion than the parental ‘PTO-only’ ODN. They have identified one further novel PTO-ODN being similarly active on canine TLR9-21 fusion as 2006-PTO: thio9-5. Furthermore Ling1-PTO proved to be a potent PTO-ODN (see FIG. 11).

Experiment 7:

Here some PTO versions of PDE oligonucleotides were tested, that proved to be highly active on chicken TLR21, when combined with 5′- and 3′dG runs. The PTO versions, however, lack the 5′- and 3′dG runs (therefore minus G, ‘mG’)

V_(max (mOD/) EC₅₀ (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgt 6.3 311 tttgtcgtt X4qu-PTOmG ttcgttttcgttttc 12.2 328 gttttcgtt X4pe-PTOmG ttcgttttcgttttc 5.3 313 gttttcgttttcgtt X4-I-tr-PTOmG tttcgttttttcgtt 10.1 332 ttttcgttt X4-I-qu-PTOmG tttcgttttttcgttt 6.2 262 tttcgttttttcgttt X4-II-tr-PTOmG ttttcgttttttttcg 11.2 299 ttttttttcgtttt

All tested ODNs proved to be highly potent with EC₅₀ and V_(max) values identical or close to the standard PTO-ODN 2006 (see FIG. 12).

Experiment 8:

Further series of PTO-ODNs based on the active elements (chicken TLR21) of ODNs X4, X43, Z11 and CC-X were tested for their potency on canine TLR9-21 fusion

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 4.0 292 X4-24-PTO ttcgttttcgttttcgttttcgtt 5.4 274 X43-24-PTO ttcgtcttcgtcttcgtcttcgtc 7.8 233 Z11-24-PTO ctcgtcctcgtcctcgtcctcgtc 9.0 237 CC-X-24- ttcgccttcgccttcgccttcgcc 10.5  235 PTO X4-30-PTO ttcgttttcgttttcgttttcgtt 3.6 280 ttcgtt X43-30-PTO ttcgtcttcgtcttcgtcttcgtc 3.6 231 ttcgtc Z11-30-PTO ctcgtcctcgtcctcgtcctcgtc 1.9 238 ctcgtc CC-X-30- ttcgccttcgccttcgccttcgcc 1.9 242 PTO ttcgcc ODN-Ling1 tcgacgtttgacgtttgacgtt 5.3 295

All new PTO-oligonucleotides have high stimulatory activity (EC₅₀ in the single digit nanomolar range) and comparable V_(max) on canine TLR9-21, in the case of Z11-30-PTO and CC-X-30-PTO with EC₅₀s below 2 nM. None of these PTO-ODNs has been mentioned yet in relation to their use in dogs (see FIGS. 13 and 14).

Experiment 9:

In this experiment repeats of the frequently used immunostimulatory elements gacgtt and gtcgtt were tested for their potency on canine TLR9-21 fusion.

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 7.1 431 GACGTT-18- gacgttgacgttgacgtt 16.1 450 PTO GACGTT-24- gacgttgacgttgacgttgacgtt 6.8 456 PTO GACGTT-30- gacgttgacgttgacgttgacgtt 1.9 419 PTO gacgtt GTCGTT-18- gtcgttgtcgttgtcgtt 12.4 397 PTO GTCGTT-24- gtcgttgtcgttgtcgttgtcgtt 5.9 369 PTO GTCGTT-30- gtcgttgtcgttgtcgttgtcgtt 9.3 416 PTO gtcgtt 2216-PTO gggggacgatcgtcgggggg 1.2 187

In the case of the repeat element gacgtt, the experiment demonstrates that repeat number matters.

The pentamer reaches an EC₅₀ below 2 nM. Somewhat unexplained is the low EC₅₀ of this new batch of 2216-PTO. However, the V_(max) value is clearly lower than for all other ODNs tested (see FIG. 15).

Experiment 10:

In this experiment repeats of triplet and quadruplet elements were tested for their potency on canine TLR9-21 fusion.

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 4.0 292 Thio-ACG-8 acgacgacgacgacgacgacgacg inactive Thio-TCG-8 tcgtcgtcgtcgtcgtcgtcgtcg 2.1 246 Thio-TCGT-6 tcgttcgttcgttcgttcgttcgt 7.2 256 Thio-TCGC-6 tcgctcgctcgctcgctcgctcgc 3.0 238 Thio-TCGA-6 tcgatcgatcgatcgatcgatcga 12.4  302 Thio-TCGG-6 tcggtcggtcggtcggtcggtcgg 4.0 226 Thio-CCGT-6 ccgtccgtccgtccgtccgtccgt 2.2 131 Thio-ACGT-6 acgtacgtacgtacgtacgtacgt 5.9 266 Thio-GCGT-6 gcgtgcgtgcgtgcgtgcgtgcgt 4.9 194 Thio-ACGA-6 acgaacgaacgaacgaacgaacga 5.1 282 Thio-CCGC-6 ccgcccgcccgcccgcccgcccgc poorly active* Thio-GCGC-6 gcgcgcgcgcgcgcgcgcgcgcgc poorly active* Thio-GCGG-6 gcgggcgggcgggcgggcgggcgg poorly active* *EC₅₀ and V_(max) calculations not possible due to poor activity

It is remarkable that while TCG-8 is highly active, ACG-8 does not show any stimulation of canine TLR9-21 fusion. In this study, the ‘SAR’ of PTO-ODN TCGT-6 was investigated in detail; the 5′T and then the 3′T was replaced with all other bases. Unexpectedly, all the derivatives proved to be highly active with respect to EC₅₀, no dramatic loss of activity could be seen. With respect to V_(max), a major loss of potency was seen for CCGT-6, a minor one for GCGT-6. The G/C-only containing PTO-ODNs were only marginally active in this assay.

This is the determination of a comprehensive structure-activity relationship for canTLR9-21 based on hexamers of tetranucleotide motifs (see FIGS. 16 and 17).

Experiment 11:

In this experiment combinations of immunomodulatory hexamer and tetramer sequences elements were tested for their potency on canine TLR9-21 fusion (see FIG. 18).

V_(max (mOD/) EC₅₀ (nM) _(min/20 ul)) PTO1 gtcgtcgtcgtcgtcgtcgtcgtc 38.2 226 PTO2 gtcgttgtcgttgtcgttgtcgtt 27.8 253 PTO3 gacgttgacgttgacgttgacgtt 23.6 265 PTO7 gtcgttgtcgacgtcgttgtcgac 29.4 299 PTO8 gacgttgtcgttgacgttgtcgtt 21.7 319 PTO9 tcgtgtcgtttcgtgtcgtttcgt 47.2 286 PTO10 tcgtgacgtttcgtgacgtttcgt 41.0 335 PTO11 gtcgtttcgtgtcgtttcgtgtcgtt 33.9 201 PTO12 gacgtttcgtgacgtttcgtgacgtt 32.2 177 PTP13 gtcgttgtcgtcgtcgttgtcgtc 49.7 230 PTO14 gacgttgtcgtcgacgttgtcgtc 30.2 231

Conclusion: it is shown that MDCK-pNifTyhyg-SEAP-pIRESpuro-canTLR9-21 is a unique screening tool for the identification of canine TLR9 ligands. A number of novel active ODNs has been identified.

Example 7 Transfection of MDCK-pNifTyhyg-SEAP with Porcine TLR9-21 Fusion Constructs a) Transfection and Selection of Clones

MDCK-pNifTyhyg-SEAK-clone15 was transfected with pIRES-puro-porcineTLR9-21. Transfectants were selected by repeated passage with medium supplemented with 300 μg/ml hygromycin and 8 μg/m1puromycin. Testing of the resulting polyclonal cell line with the standard oligonucleotide ODN-2006-PTO indicated induction of SEAP secretion. Single cell cloning was performed and 75 clones were expanded for further testing with ODN-2006-PTO. A large number of clones were identified that showed induction of SEAP. A number of clones with the best signal-to-noise ratio were chosen for expansion and to generate frozen stabilates. After retesting, clone No 20 was selected for further experiments (see FIG. 19).

b) MDCK-pNiffyhyg-SEAP-pIRESpuro-Porcine TLR9-21-Clone 20: Testing of the Stimulatory Activity of Oligonucleotides Experiment 1:

A series of phosphorothioate oligonucleotides (PTO-ODNs, thio5-4 up to thio 5-10, thio9-3 and thio9-5) was tested, together with the standard oligonucleotides from human medicine, 2006-PTO

Vmax EC₅₀ _((mOD/min/) (nM) _(20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.1 365 thio5-4 gtcgtcgtcgtc 673 458 thio5-5 gtcgtcgtcgtcgtc 436 489 thio5-6 gtcgtcgtcgtcgtcgtc 175 459 thio5-7 gtcgtcgtcgtcgtcgtcgtc 127 470 thio5-8 gtcgtcgtcgtcgtcgtcgtcgtc 43.2 426 thio5-10 gtcgtcgtcgtcgtcgtcgtcgtc 45.4 388 gtcgtc thio5- gtcgtcgtcgtcgtcgtcgtcgtc 54.9 440 8(II) thio5- gtCGtCGtCGtCGtCGtCGtCGtc 1810 553 8pde2A thio5- gtCGtcgtCGtcgtCGtcgtCGtc 159 343 8pde2B thio9-3 ttcgtcttcgtcttcgtc 217 214 thio9-5 ttcgtcttcgtcttcgtcttcgtc 73.9 390 ttcgtc

From this experiments, it can be deduced that the pIRESpuro-porcineTLR9-21-expressing MDCK-pNifTyhyg cell line that was generated is capable of defining different potencies via the calculation of EC₅₀ values.

It is shown that for immunostimulatory ODNs, with structure elements such as gtcgtc, the number of cg elements is important: 9˜7>6>5>4>3 (see table above). This experiment also immediately outlines the potential of this cell line for generation of structure-activity relationships (SAR) and lead optimization of immunostimulatory ODNs.

It was also shows that 2006-PTO known from human research are highly potent on the porcine TLR9-21 fusion protein. Furthermore, the impact of replacement of the complete (thio5-8pde2A) and partial (thio5-8pde2B) phosphorothioate bonds of the CpG elements in thio5-8 was tested. In the inventor's hands the PDE-modified versions were far less active on porcine TLR9-21 fusion than the parental ‘PTO-only’ ODN. Finally, thio9-3 and thio9-5, which are trimers and tetramers of the motif ttcgtc, respectively were tested. (Results, see FIG. 20).

Experiment 2:

Here some PTO versions of PDE oligonucleotides were tested that proved to be highly active on chicken TLR21, when combined with 5′- and 3′dG runs. The PTO versions, however, lack the 5′- and 3′dG runs (therefore minus G, ‘mG’)

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.1 365 X4qu-PTOmG ttcgttttcgttttcgttttcgtt 42.1 434 X4pe-PTOmG ttcgttttcgttttcgttttcgtt 34.3 413 ttcgtt X4-I-tr- tttcgttttttcgttttttcgttt 46.9 419 PTOmG X4-I-qu- tttcgttttttcgttttttcgttt 35.8 417 PTOmG tttcgttt X4-II-tr- ttttcgttttttttcgtttttttt 35.5 345 PTOmG cgtttt ODN-17-PTO gtcgttgtcgttgtcgtt 119 459 ODN-Ling1- tcgacgtttgacgtttgacgtt 8.1 391 PTO X4-pent- GGGGGGTTCGTTTTCGTTTTCGTT >500 PDE TTCGTTTTCGTTGGGGG

Furthermore, two PTO-ODNs from published reports (ODN17 and ODN-Ling1) were tested. While the X4-X4-I- and X4-II-PTO-derivatives all proved to be potently active with EC₅₀ values between 30 and 50 nM, X4-pent-PDE, which is highly potent on chicken TLR21 proved to be a poor stimulator, both with respect to EC₅₀ and prospective V_(max). Interestingly, while ODN-17-PTO (a gtcgtt triplett) had an EC50 above 100 nM, ODN-Ling1-PTO proved to be as active as 2006-PTO (see FIG. 21).

Experiment 3:

In this experiment repeats of triplet and quadruplet elements were tested for their potency on porcine TLR9-21 fusion.

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006- tcgtcgttttgtcgttttgtcgtt 6.1 365 PTO Thio- acgacgacgacgacgacgacgacg poorly ACG-8 active* Thio- tcgtcgtcgtcgtcgtcgtcgtcg 61.8 246 TCG-8 Thio- tcgttcgttcgttcgttcgttcgt 3.7 256 TCGT-6 Thio- tcgctcgctcgctcgctcgctcgc 50.9 238 TCGC-6 Thio- tcgatcgatcgatcgatcgatcga 104.9 302 TCGA-6 Thio- tcggtcggtcggtcggtcggtcgg 56.0 226 TCGG-6 Thio- ccgtccgtccgtccgtccgtccgt 568.0 131 CCGT-6 Thio- acgtacgtacgtacgtacgtacgt 163.2 266 ACGT-6 Thio- gcgtgcgtgcgtgcgtgcgtgcgt 85.1 194 GCGT-6 Thio- acgaacgaacgaacgaacgaacga 72.1 282 ACGA-6 Thio- ccgcccgcccgcccgcccgcccgc poorly CCGC-6 active* Thio- gcgcgcgcgcgcgcgcgcgcgcgc poorly GCGC-6 active* Thio- gcgggcgggcgggcgggcgggcgg poorly GCGG-6 active* *EC₅₀ and V_(max) calculations not possible due to poor activity

ACG-8 does not show only minor stimulation of porcine TLR9-21 fusion, while TCG-8 has an EC50 of ˜62 nM. In this study, the ‘SAR’ of PTO-ODN TCGT-6 was investigated in detail; the 5′T and then the 3′T was replaced with all other bases. It turned out that with respect to EC₅₀, TCGT-6 was clearly the best derivative, performing even better than the standard 2006-PTO. Like for canTLR9-21, with respect to V_(max), a major loss of potency on porcineTLR9-21 was seen for CCGT-6, a minor one for GCGT-6. The G/C-only containing PTO-ODNs were only marginally active in this assay, with GCGC-6 being the best one.

This is the determination of a comprehensive structure-activity relationship for porcineTLR9-21 based on hexamers of tetranucleotide motifs (see FIGS. 22 and 23).

Experiment 4:

Here a lead optimization was attempted based upon possibly active elements form the published oligonucleotides 1668-PTO, 2216-PTO and 2395-PTO. These ‘active elements’ are underlined and/or in Italic in the parental ODN and then arranged in repeats in the mod1/2 ODNs:

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.7 410 2007-PTO tcgtcgttttgtcgttttgtcgtt 27.3 376 1668-PTO tcca tgacgtt cctgatgct 17.0 388 1668-mod1 gacgttgacgttgacgttgacgtt 10.0 457 1668-mod2 tgacgttctgacgttctgacgttc 16.5 434 tgacgttc 2216-PTO gggggacgatcgtcgggggg 249.0 361 2216-mod1 gacgatcgtcgacgatcgtc 53.1 447 2216-mod2 gacgatcgtcgacgatcgtcgacg 19.0 448 atcgtc 2395-PTO tcgtcgttttcggcgcgcgccg 16.7 301 2395-mod1 tcgtcgttttcgtcgtcgttttcg 15.1 391 2395-mod2 tcgtcgttttcgtcgtcgttttcg 12.3 407 tcgtcgttttcg

Results: see FIGS. 24, 25 and 26.

Experiment 5:

In this experiment repeats of the frequently used immunostimulatory elements gacgtt and gtcgtt were tested for their potency on porcine TLR9-21 fusion.

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgt 6.7 410 cgtt GACGTT-18-PTO gacgttgacgttgacgtt 60.2 405 GACGTT-24-PTO gacgttgacgttgacgttgac 34.0 421 gtt GACGTT-30-PTO gacgttgacgttgacgttgac 30.2 399 gttgacgtt GTCGTT-18-PTO gtcgttgtcgttgtcgtt 34.6 325 GTCGTT-24-PTO gtcgttgtcgttgtcgttgtc 20.0 354 gtt GTCGTT-30-PTO gtcgttgtcgttgtcgttgtc 21.6 347 gttgtcgtt X4-pent-PDE GGGGGGTTCGTTTTCGTTTTC >500 — GTTTTCGTTTTCGTTGGGGG

Results: see FIG. 27. Experiment 6:

Here a ‘lead optimization’ was attempted based upon possible active elements form the published oligonucleotide 2007-PTO.

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt 6.7 410 2007-PTO tcgtcgttgtcgttttgtcgtt 27.3 378 2007-mod1 tcgtcgttgtcgttttgtcgtt 32.7 439 gtcgtt 2007-mod2 tcgtcgtcgtcgttgtcgtttt 28.5 436 gtcgtt 2007-mod3 tcgtcgtcgtcgttgtcgtttt 31.7 425 gtcgttgtcgtt 2007-dimer tcgtcgttgtcgttttgtcgtt 8.9 351 tcgtcgttgtcgttttgtcgtt

Results: see FIG. 28. Experiment 7:

Further series of PTO-ODNs based on the active elements (chicken TLR21) of ODNs X4, X43, Z11 and CC-X were tested for their potency on porcine TLR9-21 fusion

EC₅₀ V_(max (mOD/) (nM) _(min/20 ul)) 2006-PTO tcgtcgttttgtcgttttgtcgtt  5.1 369 X4-24-PTO ttcgttttcgttttcgttttcgtt 22.5 479 X43-24-PTO ttcgtcttcgtcttcgtcttcgtc 36.9 454 Z11-24-PTO ctcgtcctcgtcctcgtcctcgtc 20.8 498 CC-X-24- ttcgccttcgccttcgccttcgcc 92.2 469 PTO X4-30-PTO ttcgttttcgttttcgttttcgtt 24.4 447 ttcgtt X43-30-PTO ttcgtcttcgtcttcgtcttcgtc 23.9 383 ttcgtc Z11-30-PTO ctcgtcctcgtcctcgtcctcgtc 12.6 385 ctcgtc CC-X-30- ttcgccttcgccttcgccttcgcc 47.3 395 PTO ttcgcc

Most new PTO-oligonucleotides have high stimulatory activity (EC₅₀ in the single digit nanomolar range) and comparable V_(max) on porcine TLR9-21. Particularly potent appears to be the motif of Z11 (ctcgtc). None of these PTO-ODNs has been mentioned yet in the context porcine (see FIGS. 29 and 30).

Experiment 8:

In this experiment combinations of immunomodulatory hexamer and tetramer sequences elements were tested for their potency on porcine TLR9-21 fusion.

V_(max (mOD/) EC₅₀ (nM) _(min/20 ul)) PTO1 gtcgtcgtcgtcgtcgtcgtcgtc 55.9 499 PTO2 gtcgttgtcgttgtcgttgtcgtt 28.0 472 PTO3 gacgttgacgttgacgttgacgtt 49.1 503 PTO7 gtcgttgtcgacgtcgttgtcgac 23.7 460 PTO8 gacgttgtcgttgacgttgtcgtt 38.5 442 PTO9 tcgtgtcgtttcgtgtcgtttcgt 35.6 460 PTO10 tcgtgacgtttcgtgacgtttcgt 22.4 427 PTO11 gtcgtttcgtgtcgtttcgtgtcgtt 38.8 438 PTO12 gacgtttcgtgacgtttcgtgacgtt 63.8 469 PTP13 gtcgttgtcgtcgtcgttgtcgtc 45.9 456 PTO14 gacgttgtcgtcgacgttgtcgtc 42.4 479

In this experiment, various combinations of gtcgtc-, gtcgtt-, gtcgac- and tcgt-containing PTO-ODNs proved to be of similar double digit nanomolar potency on porcine TLR9-21 (see FIG. 31).

Example 8 Experimental Design

Two groups of five (N=5) Beagle puppies of 3-4 months of age, not vaccinated against Rabies, of which the bitches were not vaccinated the past 12 month against Rabies were used. The puppies were vaccinated with 1 ml of the respective vaccine compositions. Immediately before vaccination (T=0) and at T=2, T=4, T=6, T=8, T=12, T=16, T=20 and T=24 weeks post vaccination, blood samples were taken and the antibody titers against Rabies virus were determined

Groups and Vaccination

Dose Immunostimulator Group N = Vaccine volume Supplement Concentration 1 5 Nobivac ® 1 ml — — Rabies 2 5 Nobivac ® 1 ml Thio-tcg-8- 5 μg/1 dose Rabies PTO

Vaccine Nobivac® Rabies

Formulation: commercially available vaccine Presentation: 10 ml flacons

Supplier: Intervet International BV, Boxmeer, The Netherlands Dosage and Administration

The puppies were vaccinated subcutaneously (s.c.) in the neck with 1 ml of Nobivac® Rabies vaccine with (group 2) or without (group 1) the addition of 5 μg Thio-tcg-8-PTO (TCGTCGTCGTCGTCGTCGTCGTCG) per 1 ml.

Induction of Antibodies

Directly before vaccination (T=0) and at T=2, T=4, T=6, T=8, T=12, T=16, T=20 and T=24 weeks post vaccination, blood samples were taken from each puppy. Blood samples were allowed to clot over night at 2-8° C. After centrifugation the serum was transferred into appropriate containers and stored at −20° C. until analysis. The antibody titer against Rabies in the serum was determined using the Rapid Fluorescent Focus Inhibition Test (RFFIT) which is a virus neutralization test.

Rapid Fluorescent Focus Inhibition Test (RFFIT)

RFFIT has been internationally recognized as the standard in vitro test for quantifying the presence of Rabies neutralizing antibodies. Serial 3-fold dilutions of the sera to be examined were made and mixed with an equal volume of a Rabies virus-suspension containing a standard dose (according to WHO/PHEUR with a titer between 30-300 Focus Forming Units (FFU)). The sera/virus mixture were incubated at 37° C. and 5% CO₂ for 90 minutes. To grow non-neutralized virus after a pre-incubation period, susceptible cells (BHK cells) were added into the mixture and incubated for 24 hour at 37° C. and 5% CO₂ to form a monolayer. After incubation and Rabies virus specific immuno-staining, the monolayers were observed for fluorescent foci by microscopy after which the titers (in IU/ml) were calculated.

Results:

As can be seen from FIG. 32, the anti-rabies virus titre found in dogs that received the Nobivac rabies vaccine and the CpG ODN Thio-tcg-8-PTO (TCGTCGTCGTCGTCGTCGTCGTCG) is three times the amount of that of the same rabies vaccine without this CpG ODN. 

1-29. (canceled)
 30. An immunostimulatory non-methylated phosphorothioate (PTO) oligodeoxynucleotide having the general formula selected from the group consisting of: (i) [tcg]_(n), wherein n ≧ 6; (ii) [tcgN1]_(n), wherein N1 = c or g and n ≧ 6; (iii) [N1cgt]_(n), wherein N1 = g or c or a or t and n ≧ 6; (iv) [gacgtt]_(n),  wherein n ≧ 4; (v) [gacgatcgtc]_(n),  wherein n ≧ 3; (vi) [tcgtcgttttcg]_(n),  wherein n ≧ 3, (vii) [tcgtcgttgtcgttttgtcgtt]_(n),  wherein n ≧ 2; (viii) (t_(x)[ttcgtt]t_(y))_(n), wherein n ≧ 5, x = 0-5 and y = 0-5; (ix) [ttcgN₁]_(n), wherein N₁ = t or c and wherein n ≧ 5; (x) [N₁tcgtc]_(n),  wherein N₁ = t or c and wherein n ≧ 5; (xi) [gN₁cgtt]_(n),  wherein n ≧ 4 and N₁ = a or t; and (xii) [acga]_(n),  wherein n ≧
 6.


31. The oligodeoxynucleotide claim 30, wherein said oligodeoxynucleotide is coupled to a carrier or hapten.
 32. A vector comprising the oligodeoxynucleotide of claim
 30. 33. A vaccine for preventing or combating an infectious disease, wherein said vaccine comprises an immunostimulatory amount of the oligodeoxynucleotide of claim 30, an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier.
 34. A vaccine for preventing or combating an infectious disease, wherein said vaccine comprises an immunostimulatory amount of the oligodeoxynucleotide of claim 30; wherein said oligodeoxynucleotide is coupled to a carrier or hapten, an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier.
 35. A vaccine for preventing or combating an infectious disease, wherein said vaccine comprises a vector comprising the oligodeoxynucleotide of claim 30, an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier.
 36. A vaccine for preventing or combating an infectious disease, wherein said vaccine comprises a vector comprising the oligodeoxynucleotide of claim 30; and wherein said oligodeoxynucleotide is coupled to a carrier or hapten, an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier.
 37. The immunostimulatory non-methylated oligodeoxynucleotide of claim 30 in combination with an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier for use as a medicament.
 38. The immunostimulatory non-methylated oligodeoxynucleotide of claim 30; wherein said oligodeoxynucleotide is coupled to a carrier or hapten, in combination with an immunological amount of an antigen component or genetic information encoding an antigen component, and a pharmaceutically acceptable carrier for use as a medicament.
 39. A hybrid toll-like receptor (hybrid TLR), wherein said hybrid TLR comprises a Toll-interleukin I receptor-resistance (TIR) domain of poultry TLR21 and an extracellular ligand-binding domain of a mammalian TLR9.
 40. The hybrid TLR of claim 39, wherein said extracellular ligand-binding domain of a mammalian TLR9 is a human, canine, porcine or bovine TLR9.
 41. A cell comprising a hybrid toll-like receptor (hybrid TLR); wherein said hybrid TLR comprises a Toll-interleukin I receptor-resistance (TIR) domain of poultry TLR21 and an extracellular ligand-binding domain of a mammalian TLR9.
 42. The cell of claim 41, wherein said cell comprises a plasmid comprising an NF-κB reporter gene.
 43. The cell of claim 42 wherein said plasmid is stably maintained in the cell.
 44. The cell of claim 42 wherein said reporter gene is a gene encoding secreted alkaline phosphatase.
 45. The cell of claim 41, wherein said cell is a HEK293 cell.
 46. The cell of claim 41, wherein said cell is an MDCK cell.
 47. A method for the detection of immunostimulatory oligodeoxynucleotides, wherein said method comprises the steps of: a) contacting an oligodeoxynucleotide with the cell of claim 42; and b) detecting the level of an expression product of the reporter gene.
 48. A method for the detection of immunostimulatory oligodeoxynucleotides, wherein said method comprises the steps of: a) contacting an oligodeoxynucleotide with the cell of claim 41; and b) detecting the level of an expression product of the reporter gene; wherein the product of the reporter gene is secreted alkaline phosphatase. 